A rapidly deployable optoelectronic integrated outdoor cabinet for highway scenes

By using a rapid deployment optoelectronic integrated outdoor enclosure that engages with a primary bevel gear and a primary bevel gear, combined with a servo motor drive and a rapid fixing mechanism, the problem of long deployment cycles and poor adaptability of existing enclosures is solved. This enables rapid movement and stable fixing of the enclosure, meeting the temporary communication and power supply needs of highways.

CN224419085UActive Publication Date: 2026-06-26ANHUI WANTONG TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ANHUI WANTONG TECH
Filing Date
2025-07-24
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing integrated chassis have long deployment cycles and poor adaptability on highways, and cannot be moved or fixed quickly, thus failing to meet temporary and short-term communication and power supply needs.

Method used

A rapid deployment photovoltaic integrated outdoor enclosure was designed, which includes an active bevel gear meshing with a first bevel gear. Combined with a rapid fixing mechanism, the enclosure is moved quickly and fixed stably by a servo motor driving a rotating rod and a lead screw system. It is equipped with solar panels and a UPS power supply system.

Benefits of technology

It enables rapid deployment and stable fixation of the chassis, adapts to the temporary and short-term communication and power supply needs of highways, and ensures the continuous operation of the equipment in various environments.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224419085U_ABST
    Figure CN224419085U_ABST
Patent Text Reader

Abstract

The utility model discloses a kind of for expressway scene's fast deployable photoelectric integrated outdoor machine case, it is related to expressway communication and power supply technical field.The utility model includes machine case body, machine case body bottom is fixed with base, rotating rod is rotatably arranged in the inside front side of base, driving bevel gear is fixed in the rear end of rotating rod, the rear side of driving bevel gear is meshed with first bevel gear, first screw rod is arranged in the inside vertical direction of base, first bevel gear is arranged on first screw rod, movable rack is screw-threaded on first screw rod, the bottom of movable rack is installed with a plurality of universal wheel, under the joint action of driving bevel gear, first bevel gear and first screw rod, the up and down movement of movable rack is conveniently adjusted, and then the movement and fixed of machine case body are facilitated, when facing natural disaster, traffic jam and other emergent conditions, the purpose of realizing fast deployment temporary communication and power supply system is facilitated.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model belongs to the field of highway communication and power supply technology, and in particular relates to a rapidly deployable optoelectronic integrated outdoor unit for highway scenarios. Background Technology

[0002] my country's highway construction has developed rapidly, and its supporting facilities, such as lane cameras, license plate recognition systems, vehicle type classification systems, ETC gantries, loop detectors, automatic barrier gates, and traffic lights, have been widely used in the construction and use of highways. In order to ensure smooth traffic and effective supervision, integrated cabinets are often required for the communication and power supply of the hardware equipment.

[0003] Currently, most existing integrated chassis are fixed outdoors, resulting in long deployment cycles, poor adaptability, and inefficient energy utilization. They cannot meet the immediate needs of modern highway management. In the face of emergencies such as natural disasters and traffic congestion, the existing chassis are too large to be moved or fixed quickly, thus hindering the rapid deployment of temporary communication and power supply systems to meet the temporary and short-term communication and power supply needs of highways, leading to poor performance.

[0004] To address the aforementioned issues, we propose a rapidly deployable integrated optoelectronic outdoor enclosure for highway scenarios. Utility Model Content

[0005] Technical solution

[0006] To address the aforementioned technical problems, this utility model provides a rapidly deployable integrated optoelectronic outdoor enclosure for highway scenarios, comprising an enclosure body, a base fixed to the bottom of the enclosure body, a rotating rod rotatably mounted on the front side inside the base, a drive bevel gear fixed to the rear end of the rotating rod, a first bevel gear meshing with the rear side of the drive bevel gear, a first lead screw mounted vertically inside the base, the first bevel gear mounted on the first lead screw, a movable frame threaded onto the first lead screw, several universal wheels mounted on the bottom of the movable frame, and a quick-fixing mechanism provided around the periphery of the base.

[0007] The quick-fixing mechanism includes a second lead screw, a second bevel gear, a wedge block, a pressing rod, a pressing plate, a support plate, a positioning hole, and a spring. Several second lead screws are arranged around the first bevel gear. The second bevel gear is fixed to one end of the second lead screw near the first lead screw, and the second bevel gear meshes with the first bevel gear. The wedge block is threaded onto the second lead screw.

[0008] The outer wall of the base has several storage slots, and the inner wall of each storage slot has a through hole. The extrusion rod is movably engaged with the through hole. The extrusion plate is inclinedly fixed at one end of the extrusion rod, and the inclined surface of the wedge block engages with the extrusion plate. The spring is sleeved on the outside of the extrusion rod, and both ends of the spring are fixedly connected to the extrusion plate and the base, respectively. The support plate is fixed at the end of the extrusion rod away from the extrusion plate, and the support plate engages with the storage slots. Several positioning holes are formed on the support plate.

[0009] A solar panel is hinged to the top of the chassis body. An adjustable bracket is provided between the back of the solar panel and the chassis body. A partition is fixed inside the chassis body. An air switch and a surge protector are installed opposite each other on the top of the partition. A router and a UPS are installed on the lower side of the partition. A power strip is installed on one side of the inner wall of the chassis body. An Internet of Things communication module is installed inside the chassis body.

[0010] The bottom of the chassis body is fixed with several fixing plates. The second lead screw and the rotating rod are rotatably engaged with the corresponding fixing plates. A guide rod is provided on the lower side of the second lead screw. The guide rod passes through the wedge block, and the wedge block is slidably engaged with the guide rod.

[0011] A servo motor is installed on the front side of the inner wall of the base. The output end of the servo motor is connected to the front end of the rotating rod. Several limiting rods are fixed at the bottom of the chassis body. The limiting rods pass through the movable frame. The movable frame slides with the limiting rods. A limiting plate is fixed at the bottom of the limiting rods. A door is movably installed on the front side of the chassis body.

[0012] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0013] This invention utilizes the meshing action of the active bevel gear and the first bevel gear to facilitate the rotation of the first lead screw. The threaded engagement between the first lead screw and the movable frame adjusts the vertical movement of the movable frame, which in turn moves the casters vertically. This facilitates the overall movement and handling of the chassis body, as well as its rapid fixation. Combined with a quick-fixing mechanism, the bottom of the chassis body is further secured, ensuring its overall stability. This facilitates the rapid movement and fixation of the chassis body, thereby achieving the goal of quickly deploying temporary communication and power supply systems, meeting the needs of highways for temporary and short-term communication and power supply. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0015] Figure 2 This is a top view of the present invention;

[0016] Figure 3for Figure 2 Schematic diagram of the structure of the mid-section AA;

[0017] Figure 4 for Figure 3 Schematic diagram of the structure of the mid-section BB;

[0018] Figure 5 for Figure 3 Enlarged structural diagram at point C;

[0019] Figure 6 for Figure 4 Enlarged structural diagram at point D;

[0020] Figure 7 This is a structural schematic diagram from another perspective of the present invention;

[0021] Figure 8 for Figure 7 Enlarged structural diagram at point E;

[0022] Figure 9 This is a schematic diagram of the bottom structure of this utility model.

[0023] The labels in the attached diagram are as follows: 1. Chassis body; 2. Base; 3. Drive bevel gear; 4. First bevel gear; 5. First lead screw; 6. Second lead screw; 7. Second bevel gear; 8. Movable frame; 9. Casters; 10. Wedge block; 11. Storage slot; 12. Extrusion rod; 13. Extrusion plate; 14. Support plate; 15. Positioning hole; 16. Spring; 17. Solar panel; 18. Adjustment bracket; 19. Air switch; 20. Surge protector; 21. Router; 22. UPS; 23. Power strip; 24. Guide rod; 25. Servo motor; 26. Limiting rod; 27. Cabinet door. Detailed Implementation

[0024] This specific embodiment is a rapidly deployable integrated optoelectronic outdoor enclosure for highway scenarios, such as... Figures 1-9 As shown, the rapidly deployable optoelectronic integrated outdoor enclosure for highway scenarios includes an enclosure body 1, a base 2 fixed to the bottom of the enclosure body 1, a rotating rod rotatably mounted on the front side inside the base 2, a drive bevel gear 3 fixed to the rear end of the rotating rod, a first bevel gear 4 meshing with the rear side of the drive bevel gear 3, a first lead screw 5 vertically mounted inside the base 2, the first bevel gear 4 mounted on the first lead screw 5, a movable frame 8 threaded onto the first lead screw 5, several universal wheels 9 mounted on the bottom of the movable frame 8, and a quick-fixing mechanism mounted around the perimeter of the base 2.

[0025] The meshing action of the active bevel gear 3 and the first bevel gear 4 facilitates the rotation of the first lead screw 5. With the threaded engagement between the first lead screw 5 and the movable frame 8, the up-and-down movement of the movable frame 8 is adjusted, which in turn drives the up-and-down movement of the casters 9. This facilitates the overall movement and handling of the chassis body 1, and also facilitates the quick fixing of the chassis body 1. Combined with the quick fixing mechanism, it is easy to further fix the bottom of the chassis body 1, ensuring the overall stability of the chassis body 1 and making it convenient to use.

[0026] The quick-fixing mechanism includes a second lead screw 6, a second bevel gear 7, a wedge block 10, a pressing rod 12, a pressing plate 13, a support plate 14, a positioning hole 15, and a spring 16. Several second lead screws 6 are arranged around the first bevel gear 4. The second bevel gear 7 is fixed to one end of the second lead screw 6 near the first lead screw 5 and meshes with the first bevel gear 4. The wedge block 10 is threaded onto the second lead screw 6.

[0027] The outer wall of the base 2 has several storage slots 11, and the inner wall of the storage slots 11 has a through hole. The extrusion rod 12 is movably engaged with the through hole. The extrusion plate 13 is obliquely fixed to the inner end of the extrusion rod 12, and the inclined surface of the wedge block 10 is engaged with the extrusion plate 13. The spring 16 is sleeved on the outer side of the extrusion rod 12, and the two ends of the spring 16 are fixedly connected to the extrusion plate 13 and the base 2 respectively. The support plate 14 is fixed to the end of the extrusion rod 12 away from the extrusion plate 13, and the support plate 14 is engaged with the storage slots 11. Several positioning holes 15 are opened on the support plate 14.

[0028] The meshing of the first bevel gear 4 and the second bevel gear 7 facilitates the rotation of the second lead screw 6. With the threaded engagement between the wedge block 10 and the second lead screw 6, the wedge block 10 moves. Combined with the interaction between the wedge block 10 and the extrusion plate 13, and the movable engagement between the extrusion rod 12 and the circular hole, as the wedge block 10 moves, it pushes the extrusion rod 12 outward until the support plate 14 contacts the ground. With the positioning hole 15, the support plate 14 is fixed to the ground, further securing the chassis body 1 and ensuring the stability of the chassis body 1 during use.

[0029] A solar panel 17 is hinged to the top of the chassis body 1. An adjustment bracket 18 is provided between the back of the solar panel 17 and the chassis body 1. A partition is fixed inside the chassis body 1. An air switch 19 and a surge protector 20 are installed opposite each other on the top of the partition. A router 21 and a UPS 22 are installed on the lower side of the partition. A power strip 23 is installed on one side of the inner wall of the chassis body 1. An Internet of Things communication module is installed inside the chassis body 1. The solar panel 17 facilitates the conversion of solar energy into electrical energy to achieve the purpose of power supply. The UPS 22 serves as a backup power supply and can automatically switch power supply when solar energy is insufficient or at night to achieve the purpose of stable power supply and ensure the continuous operation capability of the equipment in various environments.

[0030] Several fixing plates are fixed at the bottom of the chassis body 1. The second lead screw 6 and the rotating rod are rotatably engaged with the corresponding fixing plates. A guide rod 24 is provided on the lower side of the second lead screw 6. The guide rod 24 passes through the wedge block 10. The wedge block 10 and the guide rod 24 are slidably engaged, which effectively limits and guides the wedge block 10, ensuring the stability of the wedge block 10 during movement.

[0031] A servo motor 25 is installed on the front side of the inner wall of the base 2. The output end of the servo motor 25 is connected to the front end of the rotating rod. Several limit rods 26 are fixed at the bottom of the chassis body 1. The limit rods 26 pass through the movable frame 8. The movable frame 8 slides with the limit rods 26. The bottom of the limit rods 26 is fixed with a limit plate. The limit rods 26 effectively limit and guide the movable frame 8, ensuring the stability of the movable frame 8 during the up and down movement. A door 27 is movably installed on the front side of the chassis body 1.

[0032] Example:

[0033] In the initial state, the movable frame 8 is at its lowest point, and the casters 9 are in contact with the ground. Under the action of the casters 9, the entire chassis body 1 can be quickly moved and transported to a suitable position. This solves the problems of existing integrated chassis, which are mostly fixed outdoors, have long deployment cycles, poor adaptability, and low energy efficiency, and cannot meet the immediate needs of modern highway management. In the face of emergencies such as natural disasters and traffic congestion, the existing chassis are too large to be moved and fixed quickly.

[0034] After the chassis body 1 is moved to a suitable position, the servo motor 25 is started, and the rotating rod is driven to rotate through the servo motor 25, which in turn drives the active bevel gear 3 to rotate.

[0035] The meshing action of the active bevel gear 3 and the first bevel gear 4 drives the first bevel gear 4 to rotate, which in turn drives the first lead screw 5 to rotate. Combined with the threaded engagement between the movable frame 8 and the first lead screw 5, and the sliding engagement between the movable frame 8 and the limit rod 26, the movable frame 8 is driven to move steadily upward until the caster wheel 9 leaves the ground, so that the bottom of the base 2 contacts the ground.

[0036] During this process, as the first bevel gear 4 rotates, the meshing action of the first bevel gear 4 and the second bevel gear 7 drives the second lead screw 6 on the periphery to rotate synchronously. Under the threaded engagement of the wedge block 10 and the second lead screw 6, and the sliding engagement of the wedge block 10 and the guide rod 24, the wedge block 10 is driven to move stably away from the second bevel gear 7.

[0037] As the wedge block 10 moves, the wedge block 10, in conjunction with the inclined surface of the wedge block 10 and the extrusion plate 13, and the sliding fit between the extrusion rod 12 and the round hole, exerts a squeezing and pushing effect on the extrusion plate 13, compressing the spring 16, and thus driving the extrusion rod 12 to move outward. As the extrusion rod 12 is squeezed outward, it drives the support plate 14 to move outward from the storage groove 11 until the support plate 14 contacts the ground, increasing the contact area between the bottom of the chassis body 1 and the ground, and further ensuring the overall stability of the chassis body 1.

[0038] Based on the actual situation, by driving bolts into the positioning holes 15, the support plate 14 is fixed to the ground, further fixing the bottom of the chassis body 1. This achieves the rapid installation and fixing of the chassis body 1, enabling the rapid deployment of a temporary communication and power supply system, and meeting the needs of highways for temporary and short-term communication and power supply.

[0039] It should be further noted that the installation structure, connection method or setting method of each component in this utility model are all common mechanical methods. As long as they can achieve their beneficial effects, they can be implemented. At the same time, the servo motor 25 in this utility model is purchased from the market. Those skilled in the art can install and use it according to the requirements.

[0040] All technical features in this embodiment can be freely combined according to actual needs.

[0041] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.

Claims

1. A rapidly deployable optoelectronic integrated outdoor enclosure for highway scenarios, comprising an enclosure body (1), characterized in that, The chassis body (1) has a base (2) fixed at the bottom. A rotating rod is rotatably arranged on the front side inside the base (2). An active bevel gear (3) is fixed at the rear end of the rotating rod. A first bevel gear (4) meshes with the rear side of the active bevel gear (3). A first lead screw (5) is arranged vertically inside the base (2). The first bevel gear (4) is arranged on the first lead screw (5). A movable frame (8) is threaded on the first lead screw (5). Several universal wheels (9) are installed at the bottom of the movable frame (8). A quick fixing mechanism is arranged around the base (2).

2. The rapidly deployable integrated optoelectronic outdoor enclosure for highway scenarios according to claim 1, characterized in that, The quick-fixing mechanism includes a second lead screw (6), a second bevel gear (7), a wedge block (10), a pressing rod (12), a pressing plate (13), a support plate (14), a positioning hole (15), and a spring (16). Several second lead screws (6) are arranged around the first bevel gear (4). The second bevel gear (7) is fixed at one end of the second lead screw (6) near the first lead screw (5), and the second bevel gear (7) meshes with the first bevel gear (4). The wedge block (10) is threaded onto the second lead screw (6).

3. The rapidly deployable integrated optoelectronic outdoor enclosure for highway scenarios according to claim 2, characterized in that, The base (2) has several storage slots (11) on its outer periphery. The inner wall of each storage slot (11) has a through hole. The extrusion rod (12) is movably fitted with the hole. The extrusion plate (13) is obliquely fixed to the inner end of the extrusion rod (12). The inclined surface of the wedge block (10) is fitted with the extrusion plate (13). The spring (16) is sleeved on the outside of the extrusion rod (12). Both ends of the spring (16) are fixedly connected to the extrusion plate (13) and the base (2), respectively. The support plate (14) is fixed to the end of the extrusion rod (12) away from the extrusion plate (13). The support plate (14) is fitted with the storage slot (11). Several positioning holes (15) are opened on the support plate (14).

4. The rapidly deployable integrated optoelectronic outdoor enclosure for highway scenarios according to claim 3, characterized in that, A solar panel (17) is hinged to the top of the chassis body (1). An adjustment bracket (18) is provided between the back of the solar panel (17) and the chassis body (1). A partition is fixed inside the chassis body (1). An air switch (19) and a surge protector (20) are installed opposite each other on the top of the partition. A router (21) and a UPS (22) are provided on the lower side of the partition. A power strip (23) is installed on one side of the inner wall of the chassis body (1). An Internet of Things communication module is installed inside the chassis body (1).

5. A rapidly deployable integrated optoelectronic outdoor enclosure for highway scenarios according to claim 4, characterized in that, The bottom of the chassis body (1) is fixed with several fixing plates. The second lead screw (6) and the rotating rod are rotatably engaged with the corresponding fixing plates. A guide rod (24) is provided on the lower side of the second lead screw (6). The guide rod (24) passes through the wedge block (10). The wedge block (10) and the guide rod (24) are slidably engaged.

6. A rapidly deployable integrated optoelectronic outdoor enclosure for highway scenarios according to claim 5, characterized in that, A servo motor (25) is installed on the front side of the inner wall of the base (2). The output end of the servo motor (25) is connected to the front end of the rotating rod. Several limiting rods (26) are fixed at the bottom of the chassis body (1). The limiting rods (26) pass through the movable frame (8). The movable frame (8) and the limiting rods (26) are slidably engaged. A limiting plate is fixed at the bottom of the limiting rods (26). A door (27) is movably installed on the front side of the chassis body (1).