An aerial rail type thermal imaging temperature inspection device
By introducing protective components into the aerial orbital thermal imaging temperature inspection device, the problem of magnetic charging heads being easily contaminated has been solved, achieving a stable and reliable charging connection, and improving inspection efficiency and equipment lifespan.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- SHENZHEN JIANGHUA INTELLIGENT TECHNOLOGY CO LTD
- Filing Date
- 2026-02-27
- Publication Date
- 2026-06-09
AI Technical Summary
In existing aerial track-based thermal imaging temperature inspection devices, the charging port of the magnetic charging head is easily contaminated by dust and small insects, affecting the normal connection between the inspection robot and the magnetic charging head.
A protective component, including a protective cover and a return spring, is designed to block the charging port. Combined with a limiting groove and a pressing plate, it ensures a stable connection between the magnetic charging head and the slider. The insertion plate and the limiting plate improve the accuracy and stability of the connection and prevent dust and insects from entering.
It effectively prevents dust and small insects from entering the charging port, ensures a good electrical connection between the magnetic charging head and the slider, improves inspection efficiency and equipment stability, and avoids damage caused by collisions.
Smart Images

Figure CN122171029A_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the technical field of temperature detection devices, and particularly relates to an aerial orbital thermal imaging temperature inspection device. Background Technology
[0002] An aerial track-mounted thermal imaging temperature inspection device is a device that uses a track-mounted inspection robot equipped with a thermal imager to monitor the temperature of a specific area. It mainly includes a track system, a thermal imager, a power supply system, a control unit, monitoring software, and a data transmission and storage module. Aerial track-mounted thermal imaging temperature inspection devices are primarily used for temperature monitoring in power systems, industrial production, warehousing and logistics, and data centers.
[0003] In existing aerial track-based thermal imaging temperature inspection devices, the power supply system and the inspection robot are typically connected and charged via a magnetic charging head. When the inspection robot moves to a designated location, it automatically attaches to the magnetic charging head for charging. However, in actual use, because the charging port of the magnetic charging head is often open, dust and small insects can easily enter the charging port, thus affecting the normal connection between the inspection robot and the magnetic charging head.
[0004] Therefore, it is necessary to invent an aerial orbital thermal imaging temperature inspection device to solve the above problems. Summary of the Invention
[0005] To address the aforementioned problems, this invention provides an aerial orbital thermal imaging temperature inspection device to solve the issues raised in the background section.
[0006] To achieve the above objectives, the present invention provides the following technical solution: an aerial track-type thermal imaging temperature inspection device, comprising an electric track, a conveyor belt installed inside the electric track, a drive motor connected to the bottom of one end of the electric track to drive the conveyor belt, a strip-shaped limiting hole penetrating the top of the other end of the electric track, a magnetic charging head slidably installed inside the limiting hole, a charging socket opened on the side of the magnetic charging head near the drive motor, a charging cable connected to the top of the magnetic charging head, a protective component provided at the opening of the charging socket, a thermal imager installed at the bottom of the electric track, and a lithium battery installed inside the thermal imager, a slider detachably installed on the top of the thermal imager, the slider being installed at the bottom of the electric track and connected to the conveyor belt, a magnetic plug matching the magnetic socket being provided on the side of the slider near the magnetic charging head, and the magnetic plug being electrically connected to the lithium battery inside the thermal imager.
[0007] Furthermore, the protective assembly includes a protective cover that is vertically fitted to the opening of the charging socket. Two limiting blocks are symmetrically fixedly connected to the protective cover on the side facing the magnetic charging head. A vertical limiting groove is provided at the position where the magnetic charging head faces the limiting blocks, and the limiting blocks are slidably installed in the limiting groove. A telescopic rod is vertically fixedly connected to the top of the protective cover, and an L-shaped fixing plate is fixedly connected to the top of the telescopic rod. The fixing plate is fixedly connected to the top of the magnetic charging head. A return spring is sleeved on the telescopic rod, and the two ends of the return spring are fixedly connected to the protective cover and the fixing plate, respectively. Two vertical extrusion plates are fixedly connected to the side of the protective cover near the slider. The top and bottom of the extrusion plates are flush with the top and bottom of the protective cover, respectively. The width of the extrusion plates gradually narrows from top to bottom, and the top of the extrusion plates is higher than the top of the slider. A first roller is horizontally installed at the edge of the top of the slider near the magnetic charging head, and the first roller can contact the inclined surface of the extrusion plates.
[0008] Furthermore, the maximum extension of the telescopic rod is greater than the height of the protective cover, and when the telescopic rod is fully retracted, the bottom edge of the protective cover can be located at the top of the slider.
[0009] Furthermore, the bottom of the protective cover is designed with a slope, and the slope direction of the bottom slope of the protective cover is opposite to the slope direction of the extrusion plate. The top of the slider is provided with a strip-shaped positioning groove that matches the size of the bottom of the protective cover. The groove wall near the magnetic charging head is designed with a slope, and the slope direction of the positioning groove is the same as the slope direction of the bottom slope of the protective cover.
[0010] Furthermore, multiple second rollers are evenly and rotatably mounted on the bottom inclined surface of the protective cover, and the length direction of the second rollers is parallel to the bottom edge of the protective cover.
[0011] Furthermore, a plug plate is horizontally fixedly connected to the side of the slider near the magnetic charging head, and two L-shaped limiting plates are symmetrically fixedly connected to the bottom of the magnetic charging head. The two limiting plates are located on the front and rear sides of the plug plate, respectively, and the distance between the two limiting plates matches the width of the plug plate. The side of the plug plate near the limiting plates gradually narrows towards the middle of the plug plate, and the plug plate can be inserted between the two limiting plates.
[0012] Furthermore, the front and rear sides of the insert plate are symmetrically provided with strip-shaped deflection grooves. A bow-shaped spring is fixedly connected to the groove wall on the side of the deflection groove near the magnetic charging head. The middle part of the bow-shaped spring protrudes outside the deflection groove. The bow-shaped spring can be completely deflected into the deflection groove, and the end of the bow-shaped spring away from the magnetic charging head is always located in the deflection groove.
[0013] Furthermore, the two extrusion plates are symmetrically distributed on the front and rear sides of the magnetic plug, and the lower half of the two extrusion plates facing each other is evenly provided with bristles, which can contact the magnetic plug.
[0014] Furthermore, a buffer pad is fixedly connected to the side of the magnetic charging head away from the slider, and the buffer pad is made of soft rubber. The technical effects and advantages of this invention are as follows: 1. When using this invention, there is no need to directly contact the target object. Thus, without causing interference or damage to the object being tested, the inspection route can be set according to actual needs to achieve efficient inspection of the monitoring area. Furthermore, through track-type movement, it can quickly cover a large area, improving detection efficiency. By adjusting the monitoring threshold of the thermal imager, the temperature distribution of the target object can be accurately measured, providing reliable temperature data. Once an abnormal temperature is detected, an alarm will be issued immediately. 2. By incorporating a protective component, the present invention can cover the opening of the charging port when the magnetic charging head is not charging, thereby preventing dust and small insects in the air from entering the charging port, and thus ensuring that the magnetic charging head maintains a good electrical connection with the magnetic plug on the slider during subsequent use. 3. This invention features a positioning groove. After the magnetic charging head and the slider are connected, the protective cover can be inserted into the positioning groove under the pressure of the return spring. As the protective cover moves downward, the inclined surface at the bottom of the protective cover can generate a pushing force on the slider towards the magnetic charging head through the inclined surface of the positioning groove. This allows the magnetic charging head to be pressed further together with the slider under the action of this force, thereby improving the stability of the connection between the magnetic charging head and the slider. Furthermore, the bottom of the protective cover can also lock the slider and the magnetic charging head together with the positioning groove to prevent them from becoming loose during charging. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the overall structure of the present invention; Figure 2 This is a schematic diagram of the structure of part of the electric track in this invention; Figure 3 This is a three-dimensional schematic diagram of some of the electric tracks, thermal imagers, and conveyor belts in this invention; Figure 4 This is a three-dimensional schematic diagram of the thermal imager, magnetic charging head, slider, and some protective components in this invention; Figure 5 This is a first perspective view of the magnetic charging head, brush bristles, limiting plate, and protective components in this invention. Figure 6 This is a second perspective view of the magnetic charging head, brush bristles, limiting plate, and protective components in this invention. Figure 7 This is a three-dimensional schematic diagram of the slider, insert plate, magnetic plug, bow-shaped spring and the first roller shaft in this invention; Figure 8 This is a three-dimensional schematic diagram of the magnetic charging head and the limiting plate in this invention; Figure 9 This is a three-dimensional schematic diagram of the protective cover, limiting block, extrusion plate and second roller of the present invention.
[0016] In the diagram: 1. Electric track; 2. Conveyor belt; 3. Drive motor; 4. Limiting hole; 5. Magnetic charging head; 6. Charging socket; 7. Charging cable; 8. Protective components; 81. Protective cover; 82. Limiting block; 83. Limiting groove; 84. Telescopic rod; 85. Fixing plate; 86. Return spring; 87. Squeezing plate; 88. First roller; 9. Thermal imager; 10. Slider; 11. Magnetic plug; 12. Positioning groove; 13. Second roller; 14. Insert plate; 15. Limiting plate; 16. Bow-shaped spring; 17. Brush bristles; 18. Buffer pad. Detailed Implementation
[0017] To make the objectives, technical solutions, and advantages of the embodiments of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below in conjunction with the embodiments.
[0018] This invention provides, for example Figures 1 to 9 An aerial track-type thermal imaging temperature inspection device is shown, comprising an electric track 1, a conveyor belt 2 installed inside the electric track 1, a drive motor 3 connected to the bottom of one end of the electric track 1 to drive the conveyor belt 2, a strip-shaped limiting hole 4 penetrating through the top of the other end of the electric track 1, a magnetic charging head 5 slidably installed inside the limiting hole 4, a charging socket 6 opened on the side of the magnetic charging head 5 near the drive motor 3, a charging cable 7 connected to the top of the magnetic charging head 5, a protective component 8 provided at the opening of the charging socket 6, a thermal imager 9 installed at the bottom of the electric track 1, and a lithium battery installed inside the thermal imager 9, a slider 10 detachably installed on the top of the thermal imager 9, the slider 10 installed at the bottom of the electric track 1 and connected to the conveyor belt 2, a magnetic plug 11 matching the magnetic socket provided on the side of the slider 10 near the magnetic charging head 5, and the magnetic plug 11 electrically connected to the lithium battery inside the thermal imager 9; The protective component 8 includes a protective cover 81, which is vertically fitted to the opening of the charging socket 6. Two limiting blocks 82 are symmetrically fixedly connected to the side of the protective cover 81 facing the magnetic charging head 5. A vertical limiting groove 83 is formed at the position where the magnetic charging head 5 faces the limiting blocks 82, and the limiting blocks 82 are slidably installed in the limiting groove 83. A telescopic rod 84 is vertically fixedly connected to the top of the protective cover 81, and an L-shaped fixing plate 85 is fixedly connected to the top of the telescopic rod 84. The fixing plate 85 is fixedly connected to the top of the magnetic charging head 5. A return spring 86 is sleeved on the telescopic rod 84, and the two ends of the return spring 86 are respectively connected to the protective cover. The protective cover 81 and the fixing plate 85 are fixedly connected. Two vertical extrusion plates 87 are fixedly connected to the side of the protective cover 81 near the slider 10. The top and bottom of the extrusion plates 87 are flush with the top and bottom of the protective cover 81, respectively. The width of the extrusion plates 87 gradually narrows from top to bottom, and the top of the extrusion plates 87 is higher than the top of the slider 10. A first roller shaft 88 is horizontally installed on the edge of the top of the slider 10 near the magnetic charging head 5. The first roller shaft 88 can contact the inclined surface of the extrusion plates 87. The maximum extension of the telescopic rod 84 is greater than the height of the protective cover 81. When the telescopic rod 84 is fully retracted, the bottom edge of the protective cover 81 can be located at the top of the slider 10. Before use, the electric track 1 is installed above the area to be monitored and the monitoring threshold of the thermal imager 9 is set. During use, as the drive motor 3 is started, the conveyor belt 2 can drive the thermal imager 9 to move along the electric track 1 via the slider 10. The thermal imager 9 can collect the thermal radiation information of the target area in real time and convert it into electrical signals. After processing, these electrical signals form thermal images and corresponding temperature data. Then, the collected data can be transmitted to the control unit through the transmission module. Finally, the monitoring software stores (for easy viewing of historical records and trend analysis), analyzes and displays the data. When the temperature detected by the thermal imager 9 exceeds the preset threshold, the system will issue an alarm signal, thereby achieving efficient inspection of the monitored area without causing interference or damage to the object being detected. When the thermal imager's power is insufficient, the slider 10 can move the thermal imager toward the magnetic charging head 5. When the first roller shaft 88 on the slider 10 contacts the extrusion plate 87 on the protective cover 81, the slider 10 can drive the magnetic charging head 5 to move along the limiting hole 4 through the pushing force of the first roller shaft 88 on the extrusion plate 87. When the magnetic charging head 5 moves to the end of the limiting hole 4 away from the drive motor 3, the magnetic charging head 5 stops. At this time, as the slider 10 continues to move, the first roller shaft 88 can drive the protective cover 81 to move upward through the pushing force on the inclined surface of the extrusion plate 87. During this process, the telescopic rod 84 and the return spring 86 can be gradually compressed, while the charging socket 6 can be gradually exposed. As the protective cover 81 continues to move, when the top of the protective cover 81 is flush with the top of the slider 10, the magnetic plug 11 on the slider 10 can be inserted into the charging socket 6 on the magnetic charging head 5, thereby realizing the charging operation of the magnetic charging head 5 for the thermal imager 9. Furthermore, when the slider 10 collides with the magnetic charging head 5, as the return spring 86 is compressed, the return spring 86 can convert the collision force between the slider 10 and the magnetic charging head 5 into the elastic potential energy of the return spring 86, thereby reducing the impact of the collision on the slider 10 and the magnetic charging head 5 and preventing the slider 10 and the magnetic charging head 5 from being damaged due to the collision. After charging is complete, as the slider 10 moves the thermal imager 9 towards the drive motor 3, the magnetic charging head 5 moves along with it under the attraction of the magnetic force. When the magnetic charging head 5 moves to the end of the limiting hole 4 near the drive motor 3, it stops moving under the restriction of the limiting hole 4. At this time, as the slider 10 continues to move, it can overcome the attraction between itself and the magnetic charging head 5 and separate smoothly from it. As the slider 10 and the magnetic charging head 5 gradually separate, the protective cover 81 can move downward again under the action of the return spring 86 and block the opening of the charging socket 6, thereby preventing dust and small insects in the air from entering the charging socket 6, thus ensuring that the magnetic charging head 5 maintains a good electrical connection with the magnetic plug 11 on the slider 10 during subsequent use.
[0019] like Figures 4 to 6 As shown, the bottom of the protective cover 81 is designed with a slope, and the slope direction of the bottom slope of the protective cover 81 is opposite to the slope direction of the extrusion plate 87. The top of the slider 10 is provided with a strip-shaped positioning groove 12 that matches the size of the bottom of the protective cover 81. The groove wall of the positioning groove 12 near the magnetic charging head 5 is designed with a slope, and the slope direction of the positioning groove 12 is the same as the slope direction of the bottom slope of the protective cover 81. During frequent contact between the magnetic charging head 5 and the slider 10, the magnetism of the magnetic charging head 5 and the magnetic plug 11 may weaken, and the conveyor belt 2 in the electric track 1 may also become loose. This can cause the magnetic charging head 5 and the slider 10 to fail to adhere tightly after the drive motor 3 stops, thus affecting the charging operation of the thermal imager 9. At this time, thanks to the positioning groove 12, as the slider 10 is pressed against the extrusion plate 87 by the first roller 88, the protective cover 81 can gradually move upwards under the influence of the extrusion plate 87. When the bottom of the protective cover 81 is flush with the top of the slider 10, as the slider 10 continues to move, the magnetic plug 11 on the slider 10 can gradually be inserted into the charging socket 6. In this configuration, the bottom of the protective cover 81 can move against the top of the slider 10. When the protective cover 81 moves to a position opposite to the positioning groove 12, the protective cover 81 can move downward under the pressure of the return spring 86 and insert into the positioning groove 12. As the protective cover 81 moves downward, the bottom slope of the protective cover 81 can generate a pushing force on the slider 10 towards the magnetic charging head 5 through the slope of the positioning groove 12. This allows the magnetic charging head 5 to be pressed further together with the slider 10 under the action of this force, thereby improving the stability of the connection between the magnetic charging head 5 and the slider 10. In addition, the bottom of the protective cover 81 can also lock the slider 10 and the magnetic charging head 5 in conjunction with the positioning groove 12 to prevent them from becoming loose during the charging process. After charging is complete, as the slider 10 moves the thermal imager 9 away from the magnetic charging head 5, the magnetic charging head 5 can also move together under the attraction of the slider 10 and the restriction of the protective cover 81 on the positioning groove 12. When the magnetic charging head 5 moves to the end of the limiting hole 4 near the drive motor 3, the magnetic charging head 5 can stop moving. As the slider 10 continues to move, the protective cover 81 can move upward under the pushing force of the inclined surface of the positioning groove 12 on its bottom inclined surface, so that the protective cover 81 can gradually move out of the positioning groove 12, thereby releasing the restriction between the protective cover 81 and the positioning groove 12, so that the slider 10 and the magnetic charging head 5 can be separated smoothly.
[0020] like Figure 6 and Figure 9 As shown, a plurality of second rollers 13 are evenly and rotatably mounted on the bottom inclined surface of the protective cover 81, and the length direction of the second rollers 13 is parallel to the bottom edge of the protective cover 81. By providing a second roller 13, during the process of inserting or removing the protective cover 81 from the positioning groove 12, the second roller 13 can roll along the inclined surface of the positioning groove 12, thereby reducing the friction between the protective cover 81 and the positioning groove 12, and thus making it easier for the protective cover 81 to be inserted into or removed from the positioning groove 12.
[0021] like Figures 5 to 8As shown, a plug plate 14 is horizontally fixedly connected to the side of the slider 10 near the magnetic charging head 5. Two L-shaped limiting plates 15 are symmetrically fixedly connected to the bottom of the magnetic charging head 5. The two limiting plates 15 are located on the front and rear sides of the plug plate 14, and the distance between the two limiting plates 15 matches the width of the plug plate 14. The side of the plug plate 14 near the limiting plates 15 gradually narrows towards the middle of the plug plate 14, and the plug plate 14 can be inserted between the two limiting plates 15. The front and rear sides of the plug plate 14 are symmetrically provided with strip-shaped deflection grooves. A bow-shaped spring piece 16 is fixedly connected to the groove wall on the side of the deflection groove near the magnetic charging head 5. The middle part of the bow-shaped spring piece 16 protrudes outside the deflection groove. The bow-shaped spring piece 16 can be completely deflected into the deflection groove, and the end of the bow-shaped spring piece 16 away from the magnetic charging head 5 is always located in the deflection groove. During the frequent movement of slider 10 and magnetic charging head 5, slider 10 and magnetic charging head 5 will wear due to friction with electric track 1, causing them to wobble during movement. Consequently, when they are connected, the magnetic plug 11 on slider 10 may deviate from the charging socket 6 on magnetic charging head 5. At this time, by setting insert plate 14 and limiting plate 15, when slider 10 approaches magnetic charging head 5, insert plate 14 can be inserted between the two limiting plates 15 before slider 10 and magnetic charging head 5 are attached together, thereby restricting slider 10 and magnetic charging head 5, thus ensuring that magnetic plug 11 on slider 10 can be accurately inserted into charging socket 6 on magnetic charging head 5. Furthermore, by providing bow-shaped spring pieces 16 on the insert plate 14, when the magnetic charging head 5 moves to the end of the limiting hole 4 away from the drive motor 3 under the drive of the slider 10, as the slider 10 continues to move, the insert plate 14 can be further inserted between the two limiting plates 15. As the two bow-shaped spring pieces 16 on the front and rear sides of the insert plate 14 come into contact with the two limiting plates 15, the bow-shaped spring pieces 16 can be deflected into the deflection groove under pressure, and the bow-shaped spring pieces 16 can be pressed together with the two limiting plates 15 under their own elastic force, thereby further improving the limiting effect of the insert plate 14 and the limiting plates 15 on the magnetic charging head 5 and the slider 10, and thus ensuring the accuracy and stability of the connection between the magnetic plug 11 and the charging socket 6.
[0022] like Figure 5 As shown, the two extrusion plates 87 are symmetrically distributed on the front and rear sides of the magnetic plug 11. The lower half of the two extrusion plates 87 facing each other is evenly provided with bristles 17, and the bristles 17 can contact the magnetic plug 11. With the brush bristles 17 provided, as the slider 10 gradually moves toward the magnetic charging head 5, when the first roller shaft 88 contacts the extrusion plate 87 on the magnetic charging head 5, the magnetic plug 11 can be inserted into the brush bristles 17 between the two extrusion plates 87. As the slider 10 continues to move, when the magnetic charging head 5 moves to the end of the limiting hole 4 away from the drive motor 3 under the drive of the slider 10, the slider 10 can squeeze the inclined surfaces of the two extrusion plates 87 through the first roller shaft 88, thereby causing the extrusion plates 87 to drive the protective cover 81 to move upward. As the protective cover 81 moves upward, the brush bristles 17 between the two extrusion plates 87 can adhere to the surface of the magnetic plug 11 and brush it, thereby brushing off the dust that falls on the magnetic plug 11, thus ensuring a good electrical connection between the magnetic plug 11 and the magnetic charging head 5.
[0023] like Figure 6 As shown, a buffer pad 18 is fixedly connected to the side of the magnetic charging head 5 away from the slider 10, and the buffer pad 18 is made of soft rubber. With the buffer pad 18 provided, when the magnetic charging head 5 contacts the side of the electric track 1 away from the drive motor 3 under the action of the slider 10, the buffer pad 18 can work with the reset spring 86 to provide shock absorption protection for the magnetic charging head 5. At the same time, it can also reduce the impact force between the magnetic charging head 5 and the electric track 1, and prevent the electric track 1 from becoming loose due to frequent impacts from the magnetic charging head 5.
[0024] The above embodiments are only used to illustrate the technical solutions of the present invention, and are not intended to limit it.
Claims
1. An aerial track-mounted thermal imaging temperature inspection device, comprising an electric track (1), characterized in that: A conveyor belt (2) is installed inside the electric track (1). A drive motor (3) that drives the conveyor belt (2) is connected to the bottom of one end of the electric track (1). A strip-shaped limiting hole (4) is opened through the top of the other end of the electric track (1). A magnetic charging head (5) is slidably installed in the limiting hole (4). A charging socket (6) is opened on the side of the magnetic charging head (5) near the drive motor (3). A charging cable (7) is connected to the top of the magnetic charging head (5). A protective component is provided at the opening of the charging socket (6). (8) A thermal imager (9) is provided at the bottom of the electric track (1), and a lithium battery is provided inside the thermal imager (9). A slider (10) is detachably installed on the top of the thermal imager (9). The slider (10) is installed at the bottom of the electric track (1), and the slider (10) is connected to the conveyor belt (2). A magnetic plug (11) matching the magnetic socket is provided on the side of the slider (10) near the magnetic charging head (5). The magnetic plug (11) is electrically connected to the lithium battery inside the thermal imager (9).
2. The aerial orbital thermal imaging temperature inspection device according to claim 1, characterized in that: The protective component (8) includes a protective cover (81), which is vertically fitted to the opening of the charging socket (6). Two limiting blocks (82) are symmetrically fixedly connected to the protective cover (81) on the side facing the magnetic charging head (5). A vertical limiting groove (83) is provided at the position where the magnetic charging head (5) faces the limiting blocks (82). The limiting blocks (82) are slidably installed in the limiting groove (83). A telescopic rod (84) is vertically fixedly connected to the top of the protective cover (81). An L-shaped fixing plate (85) is fixedly connected to the top of the telescopic rod (84). The fixing plate (85) is fixedly connected to the top of the magnetic charging head (5). 4) A reset spring (86) is fitted on the upper part. The two ends of the reset spring (86) are fixedly connected to the protective cover (81) and the fixing plate (85) respectively. Two vertical extrusion plates (87) are fixedly connected to the side of the protective cover (81) near the slider (10). The top and bottom of the extrusion plates (87) are flush with the top and bottom of the protective cover (81) respectively. The width of the extrusion plates (87) gradually narrows from top to bottom, and the top of the extrusion plates (87) is higher than the top of the slider (10). A first roller shaft (88) is horizontally installed on the edge of the top of the slider (10) near the magnetic charging head (5), and the first roller shaft (88) can contact the inclined surface of the extrusion plates (87).
3. The aerial orbital thermal imaging temperature inspection device according to claim 2, characterized in that: The maximum extension of the telescopic rod (84) is greater than the height of the protective cover (81), and when the telescopic rod (84) is fully retracted, the bottom edge of the protective cover (81) can be located at the top of the slider (10).
4. The aerial orbital thermal imaging temperature inspection device according to claim 3, characterized in that: The bottom of the protective cover (81) is designed with a slope, and the slope direction of the bottom slope of the protective cover (81) is opposite to the slope direction of the extrusion plate (87). The top of the slider (10) is provided with a strip-shaped positioning groove (12) that matches the size of the bottom of the protective cover (81). The groove wall of the positioning groove (12) near the magnetic charging head (5) is designed with a slope, and the slope direction of the positioning groove (12) is the same as the slope direction of the bottom slope of the protective cover (81).
5. The aerial orbital thermal imaging temperature inspection device according to claim 4, characterized in that: Multiple second rollers (13) are evenly rotated and installed on the bottom inclined surface of the protective cover (81), and the length direction of the second rollers (13) is parallel to the bottom edge of the protective cover (81).
6. The aerial orbital thermal imaging temperature inspection device according to claim 4, characterized in that: The slider (10) is horizontally fixedly connected to a plug plate (14) on the side near the magnetic charging head (5). The bottom of the magnetic charging head (5) is symmetrically fixedly connected to two L-shaped limiting plates (15). The two limiting plates (15) are located on the front and rear sides of the plug plate (14) respectively, and the distance between the two limiting plates (15) matches the width of the plug plate (14). The side of the plug plate (14) near the limiting plate (15) gradually narrows towards the middle of the plug plate (14), and the plug plate (14) can be inserted between the two limiting plates (15).
7. The aerial orbital thermal imaging temperature inspection device according to claim 6, characterized in that: The insert plate (14) has symmetrical strip-shaped deflection grooves on its front and rear sides. A bow-shaped spring piece (16) is fixedly connected to the groove wall on the side of the deflection groove near the magnetic charging head (5). The middle part of the bow-shaped spring piece (16) protrudes outside the deflection groove. The bow-shaped spring piece (16) can be completely deflected into the deflection groove, and the end of the bow-shaped spring piece (16) away from the magnetic charging head (5) is always located in the deflection groove.
8. The aerial orbital thermal imaging temperature inspection device according to claim 3, characterized in that: Two extrusion plates (87) are symmetrically distributed on the front and rear sides of the magnetic plug (11). The lower half of the two extrusion plates (87) facing each other is uniformly provided with bristles (17), and the bristles (17) can contact the magnetic plug (11).
9. The aerial orbital thermal imaging temperature inspection device according to claim 7, characterized in that: The magnetic charging head (5) is fixedly connected to a buffer pad (18) on the side away from the slider (10), and the buffer pad (18) is made of soft rubber.