LED lamp mounting structure for a physiotherapy cabin

By introducing a protective mechanism into the LED light installation structure of the physiotherapy chamber and using damping fluid to absorb vibration energy, the problem of LED lights being prone to displacement in the vehicle-mounted physiotherapy chamber has been solved, achieving dynamic balance of the light body and extending its service life.

CN224454446UActive Publication Date: 2026-07-03TEYI TECH (HEFEI) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TEYI TECH (HEFEI) CO LTD
Filing Date
2025-06-10
Publication Date
2026-07-03

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    Figure CN224454446U_ABST
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Abstract

This utility model relates to an LED light installation structure for a physiotherapy chamber, including a light body, a mounting rail, a frame, and a protective mechanism. The mounting rail is fixed to the inner wall of the mobile physiotherapy chamber. As the vehicle-mounted physiotherapy bed moves, it vibrates. When the frame shakes, two slides slide on the surface of the upper rod, causing two push rods to swing. One end of the displacement rod is fixed to one side of the slide, and the other end of the displacement rod is fixed to a piston column. The movement of the slide can drive the displacement rod to move, thereby pushing the piston column to move within the sealed box. The movement of the slide can push the displacement rod and the piston column to move, causing the piston column to move horizontally within the sealed box. The piston column has a through hole. As the piston column moves, the damping fluid in the sealed box flows through the through hole from one side of the piston column to the other. When the piston column moves, the damping fluid is forced to flow through the through hole, generating viscous resistance, which converts mechanical vibration energy into heat energy dissipation, significantly reducing the floating amplitude of the LED light.
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Description

Technical Field

[0001] This utility model relates to the technical field of LED lamp mounting structure equipment, specifically an LED lamp mounting structure for a physiotherapy cabin. Background Technology

[0002] LED lights need to be installed inside the physiotherapy chamber for illumination. However, for emergency rescue physiotherapy chambers and vehicle-mounted mobile physiotherapy chambers, the internal components of the LED lights may shift due to the bumps that may occur during transportation, which reduces their lifespan.

[0003] For example, the authorized patent document with application number CN202122177331.0 discloses a combined structure vehicle LED light source, which solves the problem that most existing vehicle light sources are LED light source structures, with the lamp core consisting of several LED light sources fixed together. When the lamp cover is impacted, the entire lamp body needs to be replaced, increasing the cost of LED lamp replacement. A combined structure vehicle LED light source includes a lamp cover, a lamp housing, a mounting plate, and LED lamps. The surface of the mounting plate is provided with a mounting structure, which includes a connecting sleeve. The surface of the connecting sleeve slides through the mounting plate, and the LED lamp is inserted inside the connecting sleeve. The side wall of the connecting sleeve has a threaded hole, and a screw is threaded into the threaded hole. An insert block is slidably connected to the surface of the mounting plate. This utility model, by setting up a mounting structure, facilitates the individual replacement of each LED lamp, and is easy to operate, reducing the need for disassembly using other tools and saving replacement costs.

[0004] The aforementioned patent describes a mounting structure that facilitates the individual replacement of each LED light. However, LED lights inside vehicles lack adequate cushioning, leading to excessive displacement and potential misalignment of optical components. Therefore, we need to provide an LED light mounting structure for physiotherapy cabins. Utility Model Content

[0005] The purpose of this utility model is to provide an LED light mounting structure for a physiotherapy chamber. By setting a protective mechanism between the light body and the frame, the protective mechanism can absorb some of the force when the vehicle-mounted physiotherapy bed moves and vibrates, thereby reducing the swaying and floating of the light body. The elastic buffering characteristics of the protective mechanism enable the light body to maintain dynamic balance during vehicle movement, reduce rigid contact between the light body and the frame and mounting rail, extend the service life of the LED light, and solve the problems mentioned in the background art.

[0006] To achieve the above objectives, this utility model provides the following technical solution: an LED light mounting structure for a physiotherapy chamber, comprising:

[0007] The lamp body, mounting rail, frame, and protective mechanism are provided. The mounting rail is fixed to the inner wall of the mobile physiotherapy chamber. The frame is slidably installed inside the mounting rail. A protective mechanism is provided between the frame and the lamp body to reduce the displacement of the lamp body.

[0008] Preferably, the protection mechanism includes push rods, slides, and damping components. Push rods are hinged to both sides of the top of the lamp body, and slides are hinged to the top of each of the two push rods. An upper rod for sliding the two slides is fixedly installed inside the frame, and a damping component is provided on one side of each slide to prevent the slides from moving.

[0009] Preferably, the damping component includes a displacement rod, a piston rod, through holes, and a sealing box. One end of the displacement rod is fixed to the surface of the slide block, and the other end of the displacement rod is provided with a piston rod. A sealing box is slidably installed on the surface of the displacement rod, and one side of the sealing box is fixed to one side of the inner wall of the frame. Several through holes for liquid flow are opened in the piston rod.

[0010] Preferably, the sealed box is filled with damping fluid, the piston column is a rubber column, and the surface of the piston column is in close contact with the inner wall of the sealed box.

[0011] Preferably, mounting grooves are provided on both sides of the inner wall of the mounting rail, mounting strips that cooperate with the mounting grooves are fixedly installed on both sides of the frame, and positioning elements that limit the frame within the mounting rail are provided on the surface of the frame.

[0012] Preferably, the positioning component includes a plate, an adjusting rod, and a contact plate. One side of the plate is fixedly installed on the surface of the frame, and the adjusting rod is threaded into the plate. The contact plate is fixedly installed on the upper end of the adjusting rod. When the adjusting rod is rotated to move the contact plate upward, the contact plate presses against the inner wall of the mounting rail.

[0013] Preferably, the top of the slide is provided with an adhesive layer, and the top of the inner wall of the frame is provided with a contact strip that adheres to the adhesive layer.

[0014] Compared with the prior art, the beneficial effects of this utility model are:

[0015] This invention incorporates a protective mechanism between the lamp body and the frame. As the vehicle-mounted physiotherapy bed moves and vibrates, the protective mechanism absorbs some of the force, thereby reducing the swaying and floating of the lamp body. The elastic buffering characteristics of the protective mechanism allow the lamp body to maintain dynamic balance while the vehicle is in motion, reducing rigid contact between the lamp body and the frame and mounting rail, and extending the lifespan of the LED lamp. Attached Figure Description

[0016] Figure 1 This is a perspective view of the protective mechanism of this utility model;

[0017] Figure 2 This is a three-dimensional structural view of the present invention;

[0018] Figure 3 This is a perspective view of the positioning component of this utility model;

[0019] Figure 4 This is a three-dimensional sectional view of the damping component of this utility model.

[0020] In the diagram: 1. Lamp body; 2. Mounting rail; 3. Frame; 4. Protection mechanism; 41. Push rod; 42. Slide block; 43. Damping component; 431. Displacement rod; 432. Piston column; 433. Through hole; 434. Sealing box; 5. Mounting groove; 6. Mounting strip; 7. Positioning component; 71. Plate; 72. Adjusting rod; 73. Contact plate; 8. Adhesive layer; 9. Contact strip; 10. Upper rod. Detailed Implementation

[0021] 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.

[0022] Please see Figure 1-4 This utility model provides a technical solution: an LED light mounting structure for a physiotherapy chamber, comprising:

[0023] The lamp body 1, mounting rail 2, frame 3 and protective mechanism 4 are provided. The mounting rail 2 is fixed to the inner wall of the mobile physiotherapy chamber. The frame 3 is slidably installed in the mounting rail 2. The protective mechanism 4 is provided between the frame 3 and the lamp body 1 to reduce the displacement of the lamp body 1.

[0024] Specifically, the mounting rail 2 is fixed to the inner wall of the vehicle-mounted physiotherapy chamber by bolts. A sliding and adjustable frame 3 is provided inside the mounting rail 2. Since the lamp body 1 and the frame 3 are connected by a protective mechanism 4, the lamp body 1 can move together with the frame 3. The position of the lamp body 1 on the mounting rail 2 can be adjusted. When the vehicle-mounted physiotherapy bed moves and causes bumps, the protective mechanism 4 can absorb part of the force, thereby reducing the swaying and floating of the lamp body 1. The elastic buffering characteristics of the protective mechanism 4 keep the lamp body 1 in dynamic balance during vehicle movement, reduce the rigid contact between the lamp body 1 and the frame 3 and the mounting rail 2, and extend the service life of the LED lamp.

[0025] The protection mechanism 4 includes push rods 41, slides 42 and damping elements 43. Push rods 41 are hinged to both sides of the top of the lamp body 1. Slides 42 are hinged to the top of the two push rods 41. An upper rod 10 for sliding the two slides 42 is fixedly installed inside the frame 3. A damping element 43 is provided on one side of the two slides 42 to prevent the slides 42 from moving.

[0026] Furthermore, two push rods 41 are respectively hinged to the top sides of the lamp body 1, and each push rod 41 is hinged to a slide block 42. The slide block 42 slides on the surface of the upper rod 10. When the frame 3 shakes, both slide blocks 42 slide on the surface of the upper rod 10, causing the two push rods 41 to swing. Due to the setting of the damping element 43, the movement amplitude of the slide block 42 can be reduced. When the slide block 42 slides on the surface of the upper rod 10, the damping element 43 will consume vibration energy, significantly suppressing the movement speed and distance of the slide block 42, thereby reducing the shaking of the LED lamp and ensuring the stability of the illumination. At the same time, four spring parts are provided between the lamp body 1 and the frame 3 for the purpose of resetting. The spring parts do not have a buffering function, but rather a resetting effect.

[0027] The damping component 43 includes a displacement rod 431, a piston column 432, a through hole 433, and a sealing box 434. One end of the displacement rod 431 is fixed to the surface of the slide block 42, and the other end of the displacement rod 431 is provided with a piston column 432. The sealing box 434 is slidably installed on the surface of the displacement rod 431. One side of the sealing box 434 is fixed to one side of the inner wall of the frame 3. Several through holes 433 for liquid flow are opened in the piston column 432.

[0028] It is worth noting that one end of the displacement rod 431 is fixed to one side of the slide block 42, and the other end of the displacement rod 431 is fixed to the piston column 432. The movement of the slide block 42 can drive the displacement rod 431 to move, thereby pushing the piston column 432 to move within the sealing box 434. The movement of the slide block 42 can push the displacement rod 431 and the piston column 432 to move, so that the piston column 432 moves horizontally within the sealing box 434. The piston column 432 is provided with a through hole 433. As the piston column 432 moves, the liquid in the sealing box 434 flows through the through hole 433, flowing from one side of the piston column 432 to the other side, thereby generating a damping force. A sealing ring is provided at the connection between the surface of the displacement rod 431 and the sealing box 434 to improve the sealing performance within the sealing box 434.

[0029] The sealed box 434 is filled with damping fluid, the piston column 432 is a rubber column, and the surface of the piston column 432 is in close contact with the inner wall of the sealed box 434.

[0030] It is worth noting that the piston column 432 moves within the sealed box 434, which is filled with damping fluid. As the piston column 432 moves, the damping fluid in the sealed box 434 flows through the through hole 433 from one side of the piston column 432 to the other. When the piston column 432 moves, the damping fluid (silicone oil) is forced to flow through the through hole 433, generating viscous resistance, which converts mechanical vibration energy into heat energy dissipation, significantly reducing the floating amplitude of the LED lamp.

[0031] Mounting grooves 5 are provided on both sides of the inner wall of mounting rail 2. Mounting strips 6 that cooperate with mounting grooves 5 are fixedly installed on both sides of frame 3. Positioning parts 7 that limit frame 3 within mounting rail 2 are provided on the surface of frame 3.

[0032] The frame 3 has an integrally formed mounting strip 6 on both sides. The two mounting strips 6 are respectively adapted to the two mounting grooves 5. When the frame 3 is moved in the mounting rail 2, the mounting strip 6 slides in the mounting groove 5, providing a vertical limiting function. The positioning component 7 can position the frame 3 at a point on the mounting rail 2, so as to realize the adjustment of the LED light position.

[0033] The positioning component 7 includes a plate 71, an adjusting rod 72, and a contact plate 73. The plate 71 is fixedly installed on one side of the frame 3, and the adjusting rod 72 is threaded on the plate 71. The contact plate 73 is fixedly installed on the upper end of the adjusting rod 72. When the adjusting rod 72 is rotated to move the contact plate 73 upward, the contact plate 73 presses against the inner wall of the mounting rail 2.

[0034] It is worth noting that a knob is provided at the lower end of the adjusting rod 72. By rotating the knob, the adjusting rod 72 is rotated, causing the contact plate 73 at the top of the adjusting rod 72 to move upward. The top of the contact plate 73 is provided with an adhesive layer. When the top of the contact plate 73 is tightly attached to the top of the inner wall of the mounting rail 2, the friction is large. The adhesive layer at the top of the contact plate 73 has deformation capability, thus playing a strong limiting role for the frame 3. It will not fall off when the physiotherapy chamber shakes. In addition, the threads on the surface of the adjusting rod 72 have a self-locking function.

[0035] The top of the slide 42 is provided with an adhesive layer 8, and the top of the inner wall of the frame 3 is provided with a contact strip 9 that is in contact with the adhesive layer 8;

[0036] The top adhesive layer 8 of the slide block 42 is attached to the contact strip 9, making it more difficult for the slide block 42 to move and increasing friction.

[0037] The vehicle-mounted physiotherapy bed of this device vibrates as the vehicle moves. As the frame 3 shakes, both slides 42 slide on the surface of the upper rod 10, causing the two push rods 41 to swing. One end of the displacement rod 431 is fixed to one side of the slide 42, and the other end of the displacement rod 431 is fixed to the piston column 432. The movement of the slide 42 can drive the displacement rod 431 to move, thereby pushing the piston column 432 to move within the sealed box 434. The movement of the slide 42 can push the displacement rod 431 and the piston column 432 to move, causing the piston column 432 to move horizontally within the sealed box 434. The piston column 432 has a through hole 433. As the piston column 432 moves, the damping fluid in the sealed box 434 flows through the through hole 433, flowing from one side of the piston column 432 to the other side. When the piston column 432 moves, the damping fluid is forced to flow through the through hole 433, generating viscous resistance, converting mechanical vibration energy into heat energy for dissipation, and significantly reducing the floating amplitude of the LED lights.

[0038] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. An LED lamp mounting structure for a physiotherapy cabin, characterized by, include: The lamp body (1), mounting rail (2), frame (3) and protective mechanism (4) are provided. The mounting rail (2) is fixed to the inner wall of the mobile physiotherapy chamber. The frame (3) is slidably installed in the mounting rail (2). The protective mechanism (4) is provided between the frame (3) and the lamp body (1) to reduce the displacement of the lamp body (1).

2. The LED lamp mounting structure for a physiotherapy cabin according to claim 1, characterized in that: The protection mechanism (4) includes a push rod (41), a slide (42) and a damping element (43). The top two sides of the lamp body (1) are hinged with push rods (41), and the top of the two push rods (41) is hinged with slides (42). The frame (3) is fixedly installed with an upper rod (10) for sliding the two slides (42). The two slides (42) are provided with a damping element (43) on one side to make it difficult for the slides (42) to move.

3. The LED lamp mounting structure for a physiotherapy cabin according to claim 2, characterized in that: The damping component (43) includes a displacement rod (431), a piston column (432), a through hole (433), and a sealing box (434). One end of the displacement rod (431) is fixed to the surface of the slide block (42), and the other end of the displacement rod (431) is provided with a piston column (432). The sealing box (434) is slidably installed on the surface of the displacement rod (431). One side of the sealing box (434) is fixed to one side of the inner wall of the frame (3). Several through holes (433) for liquid flow are opened in the piston column (432).

4. The LED lamp mounting structure for a physiotherapy cabin according to claim 3, characterized in that: The sealed box (434) is filled with damping fluid, and the piston column (432) is a rubber column, with the surface of the piston column (432) closely attached to the inner wall of the sealed box (434).

5. The LED lamp mounting structure for a physiotherapy cabin according to claim 1, characterized in that: The mounting rail (2) has mounting grooves (5) on both sides of its inner wall. The frame (3) has mounting strips (6) that cooperate with the mounting grooves (5) on both sides. The frame (3) has positioning parts (7) on its surface that limit the frame (3) within the mounting rail (2).

6. The LED lamp mounting structure for a physiotherapy cabin according to claim 5, characterized in that: The positioning component (7) includes a plate (71), an adjusting rod (72), and a contact plate (73). The plate (71) is fixedly installed on one side of the frame (3), and the adjusting rod (72) is threadedly installed inside the plate (71). The contact plate (73) is fixedly installed on the upper end of the adjusting rod (72). When the adjusting rod (72) is rotated to move the contact plate (73) upward, the contact plate (73) presses against the inner wall of the mounting rail (2).

7. The LED lamp mounting structure for a physiotherapy cabin according to claim 2, characterized in that: The top of the slide (42) is provided with an adhesive layer (8), and the top of the inner wall of the frame (3) is provided with a contact strip (9) that fits with the adhesive layer (8).