A segmented electric linear telescopic gate utilizing photovoltaic energy storage
By designing deployable solar panels and a rotating shaft structure on the electric linear sliding gate, the problems of the need for electricity and low power generation efficiency of the electric linear sliding gate have been solved, realizing a self-powered and highly efficient electric linear sliding gate.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- YANCHENG HENGTONGDA INTELLIGENT DOOR CONTROL CO LTD
- Filing Date
- 2024-10-12
- Publication Date
- 2026-06-30
AI Technical Summary
Existing electric linear sliding gates require electricity to operate, and the area required for installing solar panels is small, resulting in low power generation efficiency.
Design a segmented electric linear telescopic gate. By installing solar panels and a pivot structure on the movable gate, the solar panels unfold during the gate's movement, increasing the contact area with sunlight, and using structures such as magnets and springs to maintain stability.
It improves the power generation efficiency of solar panels, reduces the space occupied, and realizes the function of a self-powered electric linear sliding gate.
Smart Images

Figure CN119352888B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of linear telescopic gate technology, specifically a segmented electric linear telescopic gate utilizing photovoltaic energy storage. Background Technology
[0002] A retractable door is a type of gate whose body can extend and retract freely to control the size of the gate opening and to control the passage of pedestrians or vehicles. A retractable door mainly consists of the gate body, a drive motor, tracks, and a control system.
[0003] In the existing technology, electric linear sliding gates need to be powered to operate. However, electric linear sliding gates are far from the power source, require wiring, and occupy a certain amount of space. Installing solar panels on the surface of the electric linear sliding gate can provide power to it.
[0004] However, simply fixing the solar panels to the top of the electric linear sliding gate results in a small area, low power generation, and low power generation efficiency. Summary of the Invention
[0005] The purpose of this invention is to provide a segmented electric linear telescopic gate that utilizes photovoltaic energy storage to solve the problems mentioned in the background art.
[0006] To achieve the above objectives, the present invention provides the following technical solution: a segmented electric linear telescopic gate utilizing photovoltaic energy storage, comprising:
[0007] The mounting frame has a fixed door on its surface;
[0008] A sliding door, with a baffle fixed to its surface, a telescopic rod at one end of the fixed door, a through groove on the surface of the telescopic rod, a second push block fixed to the end of the telescopic rod, a solar panel on the surface of the sliding door, and a crossbar inserted into the surface of the sliding door; and
[0009] A movable box is located on the surface of the movable door.
[0010] Preferably, the surface of the fixed door is provided with a groove, and a first push block is fixed to the end of the groove. The first push block is fixed to the surface of the fixed door. A limit groove is provided at the top of the fixed door. A limit block is fixed at the top of the movable door. The end of the limit block is inserted into the limit groove. The limit block moves with the movable door and can slide in the limit groove. A pulley is provided at the bottom of the movable box. A motor is provided inside the movable box. The motor drives the pulley at the bottom of the movable box to rotate. An energy storage component is provided inside the movable box.
[0011] Preferably, the surface of the sliding door is provided with multiple sets of solar panels, the ends of the solar panels are fixed with a rotating shaft, the solar panels are hinged to the surface of the sliding door through the rotating shaft, the solar panels can swing along the rotating shaft, the surface of the solar panels is provided with a sliding groove, and a slider is provided in the sliding groove, the slider can slide in the sliding groove.
[0012] Preferably, the surface of the slider is hinged to a crossbar via a pivot, the crossbar can swing along the pivot of the slider surface, a second magnet is fixed to the surface of the crossbar, the second magnet moves with the crossbar, the crossbar is inserted into the inside of the sliding door, and the crossbar can move inside the sliding door.
[0013] Preferably, the telescopic rod is inserted into the end of the fixed door, and a spring is provided inside the fixed door. One end of the spring is connected to the inside of the fixed door, and the other end of the spring is connected to the end of the telescopic rod. The telescopic rod extends out from the inside of the fixed door under the push of the spring.
[0014] Preferably, after the movable door moves away from the fixed door, the end of the crossbar abuts against the surface of the second push block, causing the crossbar to move toward the solar panel. When the movable door moves toward the fixed door, the end of the crossbar is inserted into the through groove on the surface of the telescopic rod.
[0015] Preferably, the surface of the movable door is fixed with a first magnet, and two sets of the first magnet are provided. When the second magnet on the surface of the crossbar moves with the crossbar to the position of the first magnet, the first magnet and the second magnet attract each other.
[0016] Preferably, a baffle is fixed to the surface of the movable door. The baffle moves with the movable door. After the movable door moves toward the fixed door, the baffle presses against the end of the telescopic rod, causing the telescopic rod to retract into the interior of the fixed door.
[0017] Preferably, the bottom of the sliding door is provided with rollers, which rotate to drive the sliding door to move, while the fixed door is fixed to the ground.
[0018] Preferably, the telescopic rods are provided in multiple sets, and the multiple sets of telescopic rods are evenly distributed at the ends of the fixed door.
[0019] Compared with the prior art, the beneficial effects of the present invention are:
[0020] The invention proposes a movable box with rollers at the bottom that rotate to drive a movable door. The movable door opens and closes. When the movable door moves to the end of the fixed door, a telescopic rod extends from the inside of the fixed door under the push of the end spring. A crossbar moving in the through groove presses against the surface of the second push block, causing the crossbar to move towards the solar panel under the pressure of the second push block. After the crossbar moves, the slider slides in the groove and lifts the solar panel, causing the solar panel to swing along the pivot. After the solar panel unfolds, the contact area with sunlight is increased. Attached Figure Description
[0021] Figure 1 This is a three-dimensional structural diagram of the present invention.
[0022] Figure 2 This is a schematic diagram of the structure of the present invention from another perspective.
[0023] Figure 3 This is a schematic cross-sectional view of the present invention.
[0024] Figure 4 for Figure 2 Enlarged schematic diagram of the structure at point A in the middle.
[0025] Figure 5 for Figure 3 Enlarged schematic diagram of the structure at point B.
[0026] In the diagram: 1. Fixed frame; 2. Fixed door; 3. First push block; 4. Limiting groove; 5. Limiting block; 6. Slot; 7. Solar panel; 8. Rotating shaft; 9. Moving door; 10. Moving box; 11. Telescopic rod; 12. Baffle; 13. Second push block; 14. First magnet; 15. Crossbar; 16. Through groove; 17. Slider; 18. Second magnet; 19. Slide groove. Detailed Implementation
[0027] To make the objectives, technical solutions, and advantages of the present invention clear and complete, the embodiments of the present invention will be further described in detail below with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are only some, not all, embodiments of the present invention, and are merely illustrative of the embodiments of the present invention. They are not intended to limit the embodiments of the present invention. All other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0028] Please see Figures 1 to 5 The present invention provides a technical solution:
[0029] Example 1: A segmented electric linear telescopic gate utilizing photovoltaic energy storage, comprising: a fixed frame 1, with a fixed door 2 fixed to the surface of the fixed frame 1; a movable door 9, with a baffle 12 fixed to the surface of the movable door 9, a telescopic rod 11 provided at the end of the fixed door 2, a through groove 16 opened on the surface of the telescopic rod 11, a second push block 13 fixed at the end of the telescopic rod 11, a solar panel 7 provided on the surface of the movable door 9, and a crossbar 15 inserted into the surface of the movable door 9; and a movable box 10, located on the surface of the movable door 9, which lifts the solar panel 7, causing the solar panel 7 to swing along the pivot 8. After the solar panel 7 is unfolded, the contact area with sunlight is increased, and when the movable door 9 moves to one side of the pivot 8, the solar panel 7 swings along the pivot 8, and the solar panel 7 is in a vertical state, reducing the space occupied.
[0030] Example 2: A slot 6 is formed on the surface of the fixed door 2, and a first push block 3 is fixed to the end of the slot 6. The first push block 3 is fixed to the surface of the fixed door 2. A limit groove 4 is formed on the top of the fixed door 2. A limit block 5 is fixed to the top of the movable door 9. The end of the limit block 5 is inserted into the limit groove 4. The limit block 5 moves with the movable door 9 and can slide in the limit groove 4. A pulley is provided at the bottom of the movable box 10. A motor is provided inside the movable box 10. The motor drives the pulley at the bottom of the movable box 10 to rotate. A power storage component is provided inside the movable box 10. Telescopic rod 11 A spring is inserted into the end of the fixed door 2. One end of the spring is connected to the inside of the fixed door 2, and the other end of the spring is connected to the end of the telescopic rod 11. The telescopic rod 11 extends out of the inside of the fixed door 2 under the push of the spring. Multiple sets of telescopic rods 11 are provided and are evenly distributed at the end of the fixed door 2. The telescopic rod 11 extends out of the inside of the fixed door 2 under the push of the end spring. The crossbar 15, which moves in the through groove 16, is pressed against the surface of the second push block 13, so that the crossbar 15 is pressed by the second push block 13 and moves towards the solar panel 7.
[0031] Multiple solar panels 7 are provided on the surface of the sliding door 9. A pivot 8 is fixed to the end of each solar panel 7. The solar panel 7 is hinged to the surface of the sliding door 9 via the pivot 8. The solar panel 7 can swing along the pivot 8. A groove 19 is provided on the surface of the solar panel 7. A slider 17 is provided in the groove 19. The slider 17 can slide in the groove 19. After the crossbar 15 moves, the slider 17 slides in the groove 19 and lifts the solar panel 7, causing the solar panel 7 to swing along the pivot 8. After the solar panel 7 is unfolded, the contact area with sunlight is increased.
[0032] A crossbar 15 is hinged to the surface of slider 17 via a pivot. The crossbar 15 can swing along the pivot of slider 17. A second magnet 18 is fixed to the surface of the crossbar 15, and the second magnet 18 moves with the crossbar 15. The crossbar 15 is inserted into the interior of sliding door 9 and can move inside the sliding door 9. After the sliding door 9 moves away from the fixed door 2, the end of the crossbar 15 abuts against the surface of the second push block 13, causing the crossbar 15 to move towards the solar panel 7. When the sliding door 9 moves towards the fixed door 2, the end of the crossbar 15 is inserted into the through groove 1 on the surface of telescopic rod 11. In section 6, a first magnet 14 is fixed to the surface of the sliding door 9. Two sets of first magnets 14 are provided. When the second magnet 18 on the surface of the crossbar 15 moves to the position of the first magnet 14 along with the crossbar 15, the first magnet 14 and the second magnet 18 attract each other. A baffle 12 is fixed to the surface of the sliding door 9. The baffle 12 moves with the sliding door 9. After the sliding door 9 moves toward the fixed door 2, the baffle 12 presses against the end of the telescopic rod 11, so that the telescopic rod 11 retracts into the interior of the fixed door 2. A roller is provided at the bottom of the sliding door 9. The roller rotates to drive the sliding door 9 to move. The fixed door 2 is fixed on the ground.
[0033] The rollers at the bottom of the movable box 10 rotate, driving the movable door 9 to move. The movement of the movable door 9 opens and closes the door. When the movable door 9 moves to the end of the fixed door 2, the telescopic rod 11 extends out from the inside of the fixed door 2 under the push of the end spring. The crossbar 15, which moves in the through groove 16, presses against the surface of the second push block 13, causing the crossbar 15 to move towards the solar panel 7 under the pressure of the second push block 13. After the crossbar 15 moves, the slider 17 slides in the slide groove 19, lifting the solar panel 7 and causing the solar panel 7 to swing along the rotating shaft 8. After the solar panel 7 unfolds, it increases the contact area with sunlight. And when the movable door 9 moves to one side of the rotating shaft 8, The solar panel 7 swings along the pivot 8, maintaining a vertical position and reducing its space occupation. The crossbar 15 moves towards the telescopic rod 11, and the second magnet 18 on the surface of the crossbar 15 moves to the position of the first magnet 14. The first magnet 14 and the second magnet 18 attract each other, stabilizing the position of the crossbar 15 and keeping the solar panel 7 stable. As the sliding door 9 moves, the crossbar 15 presses against the surface of the first push block 3, causing the solar panel 7 to swing again. This ensures that the solar panel 7 can increase its contact area with sunlight when the sliding door 9 is in a stable state. The solar panel 7 remains vertical and stable when the sliding door 9 moves.
[0034] Although the illustrative specific embodiments of this application have been described above to enable those skilled in the art to understand this application, this application is not limited to the scope of the specific embodiments. For those skilled in the art, all applications utilizing the concept of this application are protected as long as various variations are within the spirit and scope of this application as defined and determined by the appended claims.
Claims
1. A segmented electric linear telescopic gate utilizing photovoltaic energy storage, characterized in that: include: A fixed frame (1) has a fixed door (2) fixed to its surface; A sliding door (9) has a baffle (12) fixed to its surface. A telescopic rod (11) is provided at the end of a fixed door (2). A through groove (16) is provided on the surface of the telescopic rod (11). A second push block (13) is fixed at the end of the telescopic rod (11). A crossbar (15) is inserted into the surface of the sliding door (9). A movable box (10) is provided on the surface of a movable door (9). Multiple solar panels (7) are provided on the surface of the movable door (9). A pivot (8) is fixed to the end of each solar panel (7). The solar panel (7) is hinged to the surface of the movable door (9) via the pivot (8). The solar panel (7) can swing along the pivot (8). A groove (19) is provided on the surface of the solar panel (7). A slider (17) is provided in the groove (19). The slider (17) can slide in the groove (19). A slot (6) is provided on the surface of the fixed door (2). (6) has a first push block (3) fixed at its end. The first push block (3) is fixed to the surface of the fixed door (2). The top of the fixed door (2) has a limit groove (4). The top of the movable door (9) has a limit block (5) fixed. The end of the limit block (5) is inserted into the limit groove (4). The limit block (5) moves with the movable door (9). The limit block (5) can slide in the limit groove (4). The bottom of the movable box (10) is provided with a pulley. The movable box (10) is provided with a motor. The motor drives the pulley at the bottom of the movable box (10) to rotate. The movable box (10) is equipped with a power storage component. A horizontal bar (15) is hinged to the surface of the slider (17) via a pivot. The horizontal bar (15) can swing along the pivot of the slider (17). The telescopic rod (11) is inserted into the end of the fixed door (2). A spring is installed inside the fixed door (2). One end of the spring is connected to the inside of the fixed door (2), and the other end of the spring is connected to the end of the telescopic rod (11). The telescopic rod (11) extends out from the inside of the fixed door (2) under the push of the spring. The movable door (9) moves away from the fixed door (2). After the movement, the end of the crossbar (15) abuts against the surface of the second push block (13), causing the crossbar (15) to move toward the solar panel (7). When the moving door (9) moves toward the fixed door (2), the end of the crossbar (15) is inserted into the through groove (16) on the surface of the telescopic rod (11). The baffle (12) moves with the moving door (9). After the moving door (9) moves toward the fixed door (2), the baffle (12) abuts against the end of the telescopic rod (11), causing the telescopic rod (11) to retract into the interior of the fixed door (2).
2. A segmented electric linear telescopic gate utilizing photovoltaic energy storage as described in claim 1, characterized in that: The surface of the sliding door (9) is fixed with a first magnet (14), and there are two sets of the first magnet (14). The surface of the crossbar (15) is fixed with a second magnet (18). The second magnet (18) moves with the crossbar (15). The crossbar (15) is inserted into the interior of the sliding door (9). The crossbar (15) can move inside the sliding door (9). When the second magnet (18) on the surface of the crossbar (15) moves with the crossbar (15) to the position of the first magnet (14), the first magnet (14) and the second magnet (18) attract each other.
3. A segmented electric linear telescopic gate utilizing photovoltaic energy storage as described in claim 2, characterized in that: The bottom of the movable door (9) is equipped with rollers. The rollers rotate to drive the movable door (9) to move, while the fixed door (2) is fixed on the ground.
4. A segmented electric linear telescopic gate utilizing photovoltaic energy storage as described in claim 3, characterized in that: The telescopic rod (11) is provided in multiple sets, and the multiple sets of telescopic rods (11) are evenly distributed at the ends of the fixed door (2).