A floodlight mounting structure

By designing angle adjustment and connection components, the problems of unstable installation and inaccurate angle adjustment of floodlights have been solved, enabling convenient and stable installation and precise angle adjustment of floodlights, thus improving reliability and lighting effect.

CN224454516UActive Publication Date: 2026-07-03SHANGHAI HUANDONG LIGHTING TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI HUANDONG LIGHTING TECHNOLOGY CO LTD
Filing Date
2025-09-02
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing floodlight installation structures are difficult to install conveniently and stably in extreme environments, and the angle adjustment is inaccurate, posing safety hazards and affecting the lighting effect and reliability.

Method used

The system employs angle adjustment and connection components, including lead screws, knobs, moving blocks, rotating rods, fixing blocks, expansion bolts, magnetic blocks, and springs. The rotation of the lead screw drives the linear movement of the moving blocks, which in turn drives the rotating rod to achieve angle adjustment and stable installation of the floodlight. Combined with a buffer limit structure, it ensures installation stability and angle accuracy.

Benefits of technology

It enables convenient and stable installation of floodlights and precise angle adjustment, improves reliability, reduces the risk of falling off, and enhances the accuracy of the lighting range and the overall user experience.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224454516U_ABST
    Figure CN224454516U_ABST
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Abstract

This utility model provides a floodlight installation structure, relating to the field of floodlight technology. It includes a connecting plate and an angle adjustment assembly. The angle adjustment assembly includes a lead screw rotatably connected to the connecting plate, a movable block threaded onto the lead screw, and a first rotating rod rotatably connected to the movable block. In this utility model, the first connecting block is fixed to the mounting base surface by expansion bolts. Initially, a magnetic block on the connecting plate temporarily attracts the base surface using magnetic force, and the elasticity of the spring plate ensures stable installation of the floodlight. During angle adjustment, rotating the lead screw drives the movable block to move linearly, causing the first rotating rod to push and pull the mounting plate. Simultaneously, the second and third rotating rods on the fixed block are linked to form a stable support, allowing the mounting plate to rotate around the hinge point of the connecting plate, precisely adjusting the floodlight's illumination angle. This achieves convenient and stable installation, precise and stable angle adjustment, and improved reliability.
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Description

Technical Field

[0001] This utility model relates to the field of floodlight technology, and in particular to a floodlight installation structure. Background Technology

[0002] Floodlight mounting structures are commonly used in outdoor lighting systems. When designing them, the stability and weather resistance of the luminaires need to be considered. Traditional mounting structures mostly use brackets and fixing devices. However, with changes in the outdoor environment, existing designs often cannot meet the requirements of extreme conditions such as strong winds and heavy loads. Therefore, improving the strength, adjustment flexibility, and reducing maintenance needs of the mounting structure are the key points of current technological improvements.

[0003] However, in actual use, the following shortcomings still exist. For example, the existing floodlight installation structure cannot achieve convenient and stable installation, precise and stable angle adjustment, and improved reliability. Inconvenient and unstable installation can lead to time-consuming and laborious installation processes. It may also cause the floodlight to fall off due to insecure installation, posing a safety hazard. It can also affect the accuracy of the lighting position. Inaccurate and unstable angle adjustment can cause the lighting range to deviate from the expected range, failing to meet specific lighting needs, reducing efficiency, and thus affecting the overall user experience and reliability.

[0004] Therefore, this utility model proposes a floodlight installation structure to solve the above problems. Utility Model Content

[0005] The purpose of this invention is to address the shortcomings of existing technologies and propose a floodlight installation structure.

[0006] To achieve the above objectives, this utility model adopts the following technical solution: a floodlight mounting structure, including a connecting plate, and further comprising:

[0007] An angle adjustment assembly includes a lead screw rotatably connected to a connecting plate, a movable block threaded onto the lead screw, a first rotating rod rotatably connected to the movable block, a mounting plate rotatably connected to the other end of the first rotating rod, the mounting plate rotatably connected to the connecting plate, a fixed block connected to the connecting plate, a second rotating rod rotatably connected to the fixed block, a third rotating rod rotatably connected to the second rotating rod, the third rotating rod rotatably connected to the mounting plate, and a floodlight mounted on the mounting plate.

[0008] A connecting assembly includes a first connecting block connected to a connecting plate, the first connecting block being provided with an expansion bolt, a magnetic block being provided on the connecting plate, and a spring piece being provided on the connecting plate.

[0009] Furthermore, a knob is connected to one end of the lead screw.

[0010] The beneficial effects of adopting the above-mentioned further solution are: the knob at one end of the lead screw is a manual adjustment component. When the knob is turned, the lead screw can be rotated synchronously. Through the threaded engagement between the lead screw and the moving block, the rotational motion of the knob is converted into the linear motion of the moving block, thereby driving the angle adjustment component to operate and realizing convenient adjustment of the floodlight angle.

[0011] Furthermore, a locking block is connected to the mounting plate, and the floodlight is mounted on the locking block.

[0012] The beneficial effects of adopting the above-mentioned further solution are: the clips on the mounting plate serve to fix the floodlight. The floodlight is placed on the clips, and the clips adapt to the floodlight through their own structure, limiting the displacement of the floodlight on the mounting plate, ensuring that the floodlight is installed firmly, and preventing shaking or falling off during angle adjustment or use.

[0013] Furthermore, a hollow tube is connected to the fixing block, a limit rod is slidably connected inside the hollow tube, and a telescopic spring is provided inside the hollow tube.

[0014] The beneficial effects of adopting the above-mentioned further solution are: the hollow tube, the limiting rod and the telescopic spring on the fixed block form a buffer limiting structure. When the mounting plate rotates to a certain position, the mounting plate squeezes the limiting rod to slide inside the hollow tube, and the telescopic spring extends and retracts accordingly, which can buffer the impact force of movement and limit the range of movement of the component to ensure structural stability.

[0015] Furthermore, one end of the telescopic spring is connected inside the hollow tube, and the other end of the telescopic spring is connected to the limiting rod.

[0016] The beneficial effects of adopting the above-mentioned further solution are: one end of the telescopic spring is connected to the hollow tube and the other end is connected to the limiting rod. When the limiting rod is subjected to force and slides, the telescopic spring is stretched or compressed to generate elastic force. This elastic force reacts on the limiting rod, forming a buffer, reducing rigid collisions between components, and helping the limiting rod to reset after the force disappears, maintaining the dynamic balance of the structure.

[0017] Furthermore, a second connecting block is connected to the connecting plate, the spring is connected to the second connecting block, and the other end of the spring is connected to a third connecting block.

[0018] The beneficial effects of adopting the above-mentioned further solution are: during installation, the third connecting block contacts the mounting base surface, and the spring sheet deforms due to the pressure of the base surface to generate elastic force. Through the elastic force, the third connecting block is tightly attached to the base surface, which enhances the stability in the initial stage of installation and assists the magnetic block in improving the temporary fixing effect.

[0019] Compared with the prior art, the advantages and positive effects of this utility model are as follows:

[0020] In this invention, the first connecting block in the connecting assembly is fixed to the mounting base surface by expansion bolts. During the initial installation, the magnetic block on the connecting plate temporarily attracts the base surface using magnetic force, and the elasticity of the spring sheet ensures stable installation of the floodlight. When adjusting the angle, rotating the lead screw drives the moving block to move linearly, which in turn drives the first rotating rod to push and pull the mounting plate. At the same time, the second and third rotating rods on the fixed block are linked to form a stable support, causing the mounting plate to rotate around the hinge point of the connecting plate, thus precisely adjusting the illumination angle of the floodlight. This achieves convenient and stable installation, precise and stable angle adjustment, and improved reliability. Attached Figure Description

[0021] Figure 1 This is a schematic diagram of a floodlight mounting structure according to the present invention;

[0022] Figure 2 This is a side view of the structure of a floodlight mounting structure according to the present invention;

[0023] Figure 3 This is a schematic diagram of the angle adjustment component of a floodlight mounting structure according to the present invention;

[0024] Figure 4 This is a schematic diagram of a limiting buffer structure for a floodlight mounting structure according to the present invention;

[0025] Figure 5 This is a schematic diagram of the connecting component structure of a floodlight mounting structure according to the present invention.

[0026] Figure label:

[0027] 1. Connecting plate;

[0028] 2. Angle adjustment assembly; 21. Lead screw; 22. Knob; 23. Moving block; 24. First rotating rod; 25. Mounting plate; 26. Fixing block; 27. Second rotating rod; 28. Third rotating rod; 29. ​​Locking block; 210. Floodlight; 211. Hollow tube; 212. Limiting rod; 213. Telescopic spring;

[0029] 3. Connecting components; 31. First connecting block; 32. Expansion bolt; 33. Second connecting block; 34. Spring piece; 35. Third connecting block; 36. Magnetic block. Detailed Implementation

[0030] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0031] like Figures 1-5 As shown, this embodiment provides a technical solution: a floodlight mounting structure, including a connecting plate 1, and further including:

[0032] Angle adjustment assembly 2 includes a lead screw 21 rotatably connected to a connecting plate 1, a moving block 23 threadedly connected to the lead screw 21, a first rotating rod 24 rotatably connected to the moving block 23, a mounting plate 25 rotatably connected to the other end of the first rotating rod 24, the mounting plate 25 rotatably connected to the connecting plate 1, a fixing block 26 connected to the connecting plate 1, a second rotating rod 27 rotatably connected to the fixing block 26, a third rotating rod 28 rotatably connected to the second rotating rod 27, the third rotating rod 28 rotatably connected to the mounting plate 25, and a floodlight 210 mounted on the mounting plate 25.

[0033] The connecting component 3 includes a first connecting block 31 connected to the connecting plate 1. The first connecting block 31 is equipped with an expansion bolt 32. The connecting plate 1 is equipped with a magnetic block 36 and a spring piece 34. In the connecting component 3, the first connecting block 31 is fixed to the mounting base surface via the expansion bolt 32. Initially, the magnetic block 36 on the connecting plate 1 temporarily attracts the base surface using magnetic force, and the elasticity of the spring piece 34 ensures stable installation of the floodlight 210. During angle adjustment, rotating the lead screw 21 drives the moving block 23 to move linearly, causing the first rotating rod 24 to push and pull the mounting plate 25. Simultaneously, the second rotating rod 27 and the third rotating rod 28 on the fixed block 26 work together to form a stable support, allowing the mounting plate 25 to rotate around the hinge point of the connecting plate 1, precisely adjusting the illumination angle of the floodlight 210. This achieves convenient and stable installation, precise and stable angle adjustment, and improved reliability.

[0034] like Figures 1-4As shown, a knob 22 is connected to one end of the lead screw 21. The knob 22 at one end of the lead screw 21 is a manual adjustment component. When the knob 22 is rotated, the lead screw 21 can be rotated synchronously. Through the threaded engagement between the lead screw 21 and the moving block 23, the rotational motion of the knob 22 is converted into the linear motion of the moving block 23, thereby driving the angle adjustment component 2 to operate and realize convenient adjustment of the angle of the floodlight 210. A locking block 29 is connected to the mounting plate 25. The floodlight 210 is set on the locking block 29. The locking block 29 on the mounting plate 25 serves to fix the floodlight 210. The floodlight 210 is placed on the locking block 29. The locking block 29 adapts to the floodlight 210 through its own structure, limiting the displacement of the floodlight 210 on the mounting plate 25, ensuring that the floodlight 210 is installed firmly and preventing shaking or falling off during angle adjustment or use. A hollow tube 211 is connected to the fixing block 26. A limit rod is slidably connected inside the hollow tube 211. 212. A telescopic spring 213 is installed inside the hollow tube 211. The hollow tube 211, the limiting rod 212, and the telescopic spring 213 on the fixed block 26 form a buffer limiting structure. When the mounting plate 25 rotates to a certain position, the mounting plate 25 squeezes the limiting rod 212 to slide inside the hollow tube 211, and the telescopic spring 213 extends and retracts accordingly. This can buffer the impact force of movement and limit the range of movement of the components to ensure structural stability. One end of the telescopic spring 213 is connected inside the hollow tube 211, and the other end of the telescopic spring 213 is connected to the limiting rod 212. One end of the telescopic spring 213 is connected to the hollow tube 211, and the other end is connected to the limiting rod 212. When the limiting rod 212 is subjected to force and slides, the telescopic spring 213 is stretched or compressed to generate elastic force. This elastic force reacts to the limiting rod 212 to form a buffer, reduce rigid collisions between components, and help the limiting rod 212 to reset after the force disappears, maintaining the dynamic balance of the structure.

[0035] like Figures 1-2 as well as Figure 5 As shown, a second connecting block 33 is connected to the connecting plate 1, and a spring piece 34 is connected to the second connecting block 33. The other end of the spring piece 34 is connected to a third connecting block 35. During installation, the third connecting block 35 contacts the mounting base surface. The spring piece 34 deforms due to the pressure of the base surface and generates elastic force. The elastic force makes the third connecting block 35 fit tightly against the base surface, enhancing the stability in the initial stage of installation and assisting the magnetic block 36 to improve the temporary fixing effect.

[0036] Working principle:

[0037] like Figures 1-5As shown, firstly, during the installation phase, the first connecting block 31 is fixed to the mounting base surface by expansion bolts 32, providing basic support for the overall structure. Initially, the magnetic block 36 on the connecting plate 1 temporarily attracts the base surface using magnetic force, quickly achieving initial positioning. Simultaneously, the spring piece 34 on the second connecting block 33 drives the third connecting block 35 to contact the base surface. The pressure from the base surface causes the spring piece 34 to deform, generating elastic force and pushing the third connecting block 35 to tightly adhere to the base surface. This, combined with the magnetic block 36, enhances the stability of the temporary fixation and facilitates the tightening of the expansion bolts 32. During angle adjustment, in the angle adjustment assembly 2, manually rotating the knob 22 at one end of the lead screw 21 causes the lead screw 21 to rotate synchronously. Through the threaded engagement between the lead screw 21 and the moving block 23, the rotational motion is converted into linear motion of the moving block 23. The displacement of the moving block 23 pushes or pulls the first rotating rod 24, thereby... The drive mounting plate 25 rotates around the hinge point with the connecting plate 1. During this process, the second rotating rod 27 and the third rotating rod 28 on the fixed block 26 rotate synchronously with the mounting plate 25, forming a triangular stable support structure to ensure that the mounting plate 25 rotates smoothly. The locking block 29 on the mounting plate 25 restricts the displacement of the floodlight 210 through structural adaptation, ensuring the stability of the lamp during the adjustment process. When the mounting plate 25 rotates to a specific position, it will squeeze the limiting rod 212 on the fixed block 26, causing it to slide inside the hollow tube 211. At this time, the telescopic spring 213 is stretched or compressed, and the resulting elastic force reacts to the limiting rod 212, which not only buffers the impact of movement and reduces rigid collisions, but also limits the rotation range. After the force disappears, it can also help the limiting rod 212 to reset, maintain the dynamic balance of the structure, and finally achieve precise adjustment and stable operation of the floodlight 210's illumination angle.

[0038] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.

Claims

1. A floodlight mounting structure, comprising a connecting plate (1), characterized in that, Also includes: An angle adjustment assembly (2) includes a lead screw (21) rotatably connected to a connecting plate (1), a moving block (23) threadedly connected to the lead screw (21), a first rotating rod (24) rotatably connected to the moving block (23), a mounting plate (25) rotatably connected to the other end of the first rotating rod (24), the mounting plate (25) rotatably connected to the connecting plate (1), a fixing block (26) connected to the connecting plate (1), a second rotating rod (27) rotatably connected to the fixing block (26), a third rotating rod (28) rotatably connected to the second rotating rod (27), the third rotating rod (28) rotatably connected to the mounting plate (25), and a floodlight (210) mounted on the mounting plate (25). The connecting component (3) includes a first connecting block (31) connected to the connecting plate (1), an expansion bolt (32) is provided on the first connecting block (31), a magnetic block (36) is provided on the connecting plate (1), and a spring piece (34) is provided on the connecting plate (1).

2. The floodlight mounting structure according to claim 1, characterized in that: A knob (22) is connected to one end of the lead screw (21).

3. The floodlight mounting structure according to claim 1, characterized in that: A locking block (29) is connected to the mounting plate (25), and the floodlight (210) is mounted on the locking block (29).

4. The floodlight mounting structure according to claim 1, characterized in that: A hollow tube (211) is connected to the fixed block (26), a limit rod (212) is slidably connected inside the hollow tube (211), and a telescopic spring (213) is provided inside the hollow tube (211).

5. The floodlight mounting structure according to claim 4, characterized in that: One end of the telescopic spring (213) is connected inside the hollow tube (211), and the other end of the telescopic spring (213) is connected to the limiting rod (212).

6. The floodlight mounting structure according to claim 1, characterized in that: A second connecting block (33) is connected to the connecting plate (1), and a spring piece (34) is connected to the second connecting block (33). The other end of the spring piece (34) is connected to a third connecting block (35).