Energy-saving and efficient photoelectric integrated device
By introducing adjustment and heat dissipation components into the photovoltaic integrated equipment, multi-dimensional angle adjustment and heat dissipation control of the photovoltaic panel are achieved, solving the problem of low light energy capture efficiency of the photovoltaic panel and improving light energy utilization and power generation efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BEIJING CHANGFENG XINYUAN TECHNOLOGY CO LTD
- Filing Date
- 2025-08-11
- Publication Date
- 2026-06-26
AI Technical Summary
The photovoltaic panels in existing optoelectronic integrated equipment are difficult to achieve multi-dimensional light tracking, resulting in low light energy conversion efficiency, resource waste, and usage limitations.
An adjustment component and a heat dissipation component are adopted. By designing an adjustment component and a heat dissipation component, including a support column, a photovoltaic panel, an adjustment component, and a heat dissipation component, the photovoltaic panel can be adjusted in multiple dimensions by using a motor-driven moving ring and a guide plate, and the heat dissipation range can be controlled by heat dissipation holes and cylinders, thereby improving the light energy capture and conversion efficiency.
This technology enables multi-dimensional angle adjustment of photovoltaic panels, improving light energy utilization and power generation, and enhancing the practicality and heat dissipation of the equipment.
Smart Images

Figure CN224418743U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of optoelectronic integrated equipment technology, and in particular to an energy-saving and efficient optoelectronic integrated equipment. Background Technology
[0002] Photovoltaic integrated devices, as a key carrier for clean energy applications, rely on the integration of photovoltaic technology to achieve efficient solar energy conversion. These devices typically consist of solar panels, an energy control unit, and end-user power units, directly converting solar radiation into direct current (DC) electricity through the photovoltaic effect of semiconductors to drive the load. Recent technological advancements have focused on compact structures and modular functions, driving their large-scale application in outdoor lighting, monitoring systems, and mobile base stations.
[0003] When it is necessary to use photovoltaic panels to capture and utilize solar energy, most photovoltaic panels are fixed designs or have small angle adjustments, making it difficult to achieve multi-dimensional light tracking. This results in a low light energy conversion and utilization rate, which to some extent wastes resources and limits the use of the device. Utility Model Content
[0004] In view of the problems existing in the above or prior art, this utility model is proposed.
[0005] Therefore, the purpose of this utility model is to provide an energy-saving and efficient optoelectronic integrated device.
[0006] To solve the above-mentioned technical problems, this utility model provides the following technical solution: an energy-saving and efficient optoelectronic integrated device, comprising a chassis, a support column disposed on the outer wall of the chassis, and a photovoltaic panel disposed on the outer side of the support column;
[0007] And, the adjustment assembly includes a fixed plate disposed on the end face of the support column, a first movable ring disposed on the inner wall of the fixed plate, and a second movable ring disposed on the inner wall of the fixed plate and arranged in a cross shape with the first movable ring.
[0008] And, a heat dissipation assembly, including heat dissipation holes arranged in a ring array on the outer wall of the support column.
[0009] As a preferred embodiment of the energy-saving and efficient optoelectronic integrated device of this utility model, the adjustment component further includes a first motor and a second motor fixedly installed on the outer wall of the fixed plate, the output end of the first motor is fixedly connected to the outer wall of the first moving ring, and the output end of the second motor is fixedly connected to the outer wall of the second moving ring.
[0010] As a preferred embodiment of the energy-saving and efficient optoelectronic integrated device of this utility model, wherein: the fixed plate is provided with an adjusting ball inside, and the outer wall of the adjusting ball is provided with a first inner groove and a second inner groove in the horizontal and vertical directions, respectively.
[0011] As a preferred embodiment of the energy-saving and efficient optoelectronic integrated device of this utility model, wherein: the inner wall of the first inner groove is slidably connected with a first guide plate adapted to the inner wall of the first inner groove, and the inner wall of the second inner groove is slidably connected with a second guide plate adapted to the inner wall of the second inner groove.
[0012] As a preferred embodiment of the energy-saving and efficient optoelectronic integrated device of this utility model, the length of the first guide plate is greater than that of the second inner groove, and the length of the second guide plate is greater than that of the first inner groove.
[0013] As a preferred embodiment of the energy-saving and efficient optoelectronic integrated device of this utility model, the second guide plate is fixedly connected to the inner wall of the fixed plate, and a connecting rod is fixedly connected to the end face of the first guide plate.
[0014] As a preferred embodiment of the energy-saving and efficient optoelectronic integrated device of this utility model, wherein: the end of the connecting rod is fixedly connected to a mounting plate, and the outer wall of the photovoltaic panel is fixedly connected to the end face of the mounting plate.
[0015] As a preferred embodiment of the energy-saving and efficient optoelectronic integrated device of this utility model, the outer walls of the first moving ring and the second moving ring are both hollow, and the connecting rod can slide along the inner walls of the first moving ring and the second moving ring.
[0016] As a preferred embodiment of the energy-saving and efficient optoelectronic integrated device of this utility model, the heat dissipation component further includes a cylinder fixedly connected to the outer wall of the chassis and a closed cover slidably connected to the outer wall of the chassis, wherein the output end of the cylinder is fixedly connected to the end face of the closed cover.
[0017] The beneficial effects of this energy-saving and efficient optoelectronic integrated device are as follows: This device can adjust the angle at which the photovoltaic panel captures light energy by adjusting the components, thereby improving the utilization efficiency of light energy, increasing the light energy capture rate and power generation. Combined with the heat dissipation components with adjustable heat dissipation range, it can improve the heat dissipation effect of the device and enhance the overall practicality of the equipment. Attached Figure Description
[0018] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0019] Figure 1 This is a schematic diagram of the overall structure of an energy-efficient optoelectronic integrated device.
[0020] Figure 2 This is a schematic diagram of the adjustment structure of an energy-saving and efficient optoelectronic integrated device.
[0021] Figure 3 This is a schematic diagram of a partially disassembled structure of an energy-efficient and high-performance optoelectronic integrated device.
[0022] Figure 4 This is a schematic diagram of the regulating ball structure of an energy-saving and efficient optoelectronic integrated device.
[0023] The components are as follows: 1. Chassis; 2. Support column; 3. Photovoltaic panel; 4. Adjustment component; 41. Fixing plate; 42. First motor; 43. Second motor; 44. First moving ring; 45. Second moving ring; 46. Mounting plate; 47. Adjusting ball; 48. First inner groove; 49. Second inner groove; 410. First guide plate; 411. Second guide plate; 412. Connecting rod; 5. Heat dissipation component; 51. Cylinder; 52. Enclosure; 53. Heat dissipation hole. Detailed Implementation
[0024] To make the above-mentioned objectives, features and advantages of this utility model more apparent and understandable, the specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings.
[0025] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Those skilled in the art can make similar extensions without departing from the spirit of the present invention. Therefore, the present invention is not limited to the specific embodiments disclosed below.
[0026] Secondly, the term "an embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that excludes other embodiments.
[0027] Reference Figures 1 to 4An energy-efficient optoelectronic integrated device includes a chassis 1, a support column 2 fixedly connected to the outer wall of the chassis 1, and a photovoltaic panel 3 installed on the outside of the support column 2. The chassis 1 has a large diameter and is used to support the support column 2 and the adjustment component 4 to ensure that the device has sufficient stability. The photovoltaic panel 3 can be designed to be arc-shaped to improve the efficiency of light energy capture.
[0028] And, the adjusting component 4 includes a fixed plate 41 fixedly connected to the end face of the support column 2, a first moving ring 44 rotatably connected to the inner wall of the fixed plate 41, and a second moving ring 45 rotatably connected to the inner wall of the fixed plate 41 and arranged in a cross shape with the first moving ring 44; wherein, the fixed plate 41 is convex around its perimeter for connecting with the first moving ring 44 and the second moving ring 45, and its interior has sufficient space for the installation of the adjusting ball 47. Since the outer wall of the fixed plate 41 has four evenly distributed protrusions, the first moving ring 44 and the second moving ring 45 are rotatably connected to two of the opposite protrusions, so that the two moving rings are arranged in a cross shape, and the two moving rings need to be installed in a staggered manner to avoid interference.
[0029] Furthermore, the heat dissipation component 5 includes heat dissipation holes 53 arranged in a ring array on the outer wall of the support column 2. The heat dissipation holes 53 are designed in multiple groups and arranged in a ring, thereby improving the heat dissipation efficiency of the device.
[0030] Specifically, the adjustment assembly 4 also includes a first motor 42 and a second motor 43 fixedly installed on the outer wall of the fixed plate 41. The output end of the first motor 42 is fixedly connected to the outer wall of the first moving ring 44, and the output end of the second motor 43 is fixedly connected to the outer wall of the second moving ring 45. The first motor 42 is installed on the side wall of the fixed plate 41, and the second motor 43 is installed on the bottom wall of the fixed plate 41, with the two motors at a 90° angle. The first motor 42 and the second motor 43 provide driving force for the rotation of the first moving ring 44 and the second moving ring 45, respectively.
[0031] Furthermore, an adjusting ball 47 is provided inside the fixed plate 41. The outer wall of the adjusting ball 47 has a first inner groove 48 and a second inner groove 49 in the horizontal and vertical directions, respectively. The adjusting ball 47 can be moved by utilizing the design of the first inner groove 48 and the second inner groove 49 in the horizontal and vertical directions.
[0032] Preferably, the inner wall of the first inner groove 48 is slidably connected to a first guide plate 410 adapted to the inner wall of the first inner groove 48, and the inner wall of the second inner groove 49 is slidably connected to a second guide plate 411 adapted to the inner wall of the second inner groove 49. The first guide plate 410 is positioned on the inner wall of the adjusting ball 47 by the limitation of the first inner groove 48, and simultaneously, the first guide plate 410 can also control the vertical rotation of the adjusting ball 47; the two functions complement each other.
[0033] Reference Figures 1-4 The length of the first guide plate 410 is greater than that of the second inner groove 49, and the length of the second guide plate 411 is greater than that of the first inner groove 48. The lengths of the first guide plate 410 and the second guide plate 411 are greater than those of the second inner groove 49 and the first inner groove 48, respectively, thereby ensuring the realization of the limiting action of the first guide plate 410 and the second guide plate 411.
[0034] Specifically, the second guide plate 411 is fixedly connected to the inner wall of the fixed plate 41, and the end face of the first guide plate 410 is fixedly connected to the connecting rod 412. The second guide plate 411 is in a fixed state, ensuring that the adjusting ball 47 can only rotate in the vertical direction, without any change in its horizontal position, and its height remains constant.
[0035] Furthermore, a mounting plate 46 is fixedly connected to the end of the connecting rod 412, and the outer wall of the photovoltaic panel 3 is fixedly connected to the end face of the mounting plate 46. The mounting plate 46 is adapted to the inner wall of the photovoltaic panel 3, thereby ensuring the stability of the photovoltaic panel 3 installation.
[0036] Reference Figure 1 , Figure 3 and Figure 4 The outer walls of the first moving ring 44 and the second moving ring 45 are both hollow, allowing the connecting rod 412 to slide along the inner walls of the first moving ring 44 and the second moving ring 45. The hollowed-out outer walls of the first moving ring 44 and the second moving ring 45 ensure that the connecting rod 412 can slide along the inner walls of the first moving ring 44 and the second moving ring 45, thereby enabling the change of position of the photovoltaic panel 3.
[0037] Specifically, the heat dissipation assembly 5 also includes a cylinder 51 fixedly connected to the outer wall of the chassis 1 and a closed cover 52 slidably connected to the outer wall of the chassis 1, with the output end of the cylinder 51 fixedly connected to the end face of the closed cover 52.
[0038] Working principle: The support column 2 is fixed on the top of the chassis 1. One end of the support column 2 is fixedly connected to the fixing plate 41. The fixing plate 41 is cross-shaped. The first moving ring 44 and the second moving ring 45 are rotatably connected to the horizontal inner wall side and the digital inner wall side, respectively. The photovoltaic panel 3 is installed by using the connecting rod 412 and the first guide plate 410. When it is necessary to adjust the sun-facing angle of the photovoltaic panel 3;
[0039] The first motor 42, which is fixed to the outer wall of the fixed plate 41, is started. The first motor 42 drives the first moving ring 44 to rotate. Since the connecting rod 412 passes through the first moving ring 44 and the second moving ring 45, when the first moving ring 44 rotates, its inner wall will guide the connecting rod 412. One end of the connecting rod 412 is fixedly connected to the mounting plate 46, and the other end is fixedly connected to the first guide plate 410. Since the length of the first guide plate 410 is greater than that of the second inner groove 49, the contact between the first guide plate 410 and the inner wall of the adjusting ball 47 will drive the adjusting ball 47 to rotate in the vertical direction. At this time, since the second guide plate 411 is in a fixed state, the adjusting ball 47 will slide along the second guide plate 411 through the second inner groove 49, thereby realizing the adjustment of the position of the photovoltaic panel 3 in the vertical direction.
[0040] The second motor 43, installed on the bottom wall of the fixed plate 41, is started. The second motor 43 drives the second moving ring 45 to rotate synchronously. The principle is the same as that of the first moving ring 44. When the second moving ring 45 is guided by the second motor 43, it drives the connecting rod 412 and the first guide plate 410 to slide along the first inner groove 48, thereby driving the mounting plate 46 and the photovoltaic panel 3 to move synchronously, realizing the adjustment of the photovoltaic panel 3 in the horizontal position. The first moving ring 44 and the second moving ring 45 are designed to be staggered. Their center positions together form a rectangular groove through which the connecting rod 412 can pass. The first motor 42 and the second motor 43 can be started at the same time, thereby realizing the adjustment of the adjusting ball 47 in the horizontal and vertical directions at the same time, realizing rapid light tracking.
[0041] The outer wall of the enclosure 52 is provided with annularly distributed heat dissipation holes 53 to dissipate the heat inside the support column 2. The enclosure 52 can be raised and lowered by a cylinder 51 on the outer wall of the support column 2 to adjust the heat dissipation range of the heat dissipation holes 53. At the same time, when the heat dissipation holes 53 are completely blocked, it can provide a protective effect. By using the adjustment component 4 and the heat dissipation component 5 together, the light energy capture efficiency and photoelectric conversion efficiency of the device can be improved.
[0042] It should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solution of this utility model without departing from the spirit and scope of the technical solution of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.
Claims
1. An energy-efficient and high-performance optoelectronic integrated device, characterized in that: include, Chassis (1), support columns (2) disposed on the outer wall of the chassis (1), and photovoltaic panels (3) disposed on the outer side of the support columns (2); and, The adjusting assembly (4) includes a fixed plate (41) disposed on the end face of the support column (2), a first movable ring (44) disposed on the inner wall of the fixed plate (41), and a second movable ring (45) disposed on the inner wall of the fixed plate (41) and arranged in a cross shape with the first movable ring (44); and, The heat dissipation assembly (5) includes heat dissipation holes (53) arranged in a ring array on the outer wall of the support column (2).
2. The energy-saving and efficient optoelectronic integrated device as described in claim 1, characterized in that: The adjustment assembly (4) also includes a first motor (42) and a second motor (43) fixedly installed on the outer wall of the fixed plate (41). The output end of the first motor (42) is fixedly connected to the outer wall of the first moving ring (44), and the output end of the second motor (43) is fixedly connected to the outer wall of the second moving ring (45).
3. The energy-saving and efficient optoelectronic integrated device as described in claim 2, characterized in that: The fixed plate (41) is provided with an adjusting ball (47) inside. The outer wall of the adjusting ball (47) is provided with a first inner groove (48) and a second inner groove (49) in the horizontal and vertical directions, respectively.
4. The energy-saving and efficient optoelectronic integrated device as described in claim 3, characterized in that: The inner wall of the first inner groove (48) is slidably connected to a first guide plate (410) adapted to the inner wall of the first inner groove (48), and the inner wall of the second inner groove (49) is slidably connected to a second guide plate (411) adapted to the inner wall of the second inner groove (49).
5. The energy-efficient optoelectronic integrated device as described in claim 4, characterized in that: The length of the first guide plate (410) is greater than that of the second inner groove (49), and the length of the second guide plate (411) is greater than that of the first inner groove (48).
6. The energy-efficient optoelectronic integrated device as described in claim 5, characterized in that: The second guide plate (411) is fixedly connected to the inner wall of the fixed plate (41), and the end face of the first guide plate (410) is fixedly connected to the connecting rod (412).
7. The energy-saving and efficient optoelectronic integrated device as described in claim 6, characterized in that: The end of the connecting rod (412) is fixedly connected to the mounting plate (46), and the outer wall of the photovoltaic panel (3) is fixedly connected to the end face of the mounting plate (46).
8. The energy-efficient optoelectronic integrated device as described in claim 7, characterized in that: The outer walls of the first moving ring (44) and the second moving ring (45) are hollow, and the connecting rod (412) can slide along the inner walls of the first moving ring (44) and the second moving ring (45).
9. The energy-saving and efficient optoelectronic integrated device as described in claim 8, characterized in that: The heat dissipation assembly (5) also includes a cylinder (51) fixedly connected to the outer wall of the chassis (1) and a closed cover (52) slidably connected to the outer wall of the chassis (1), with the output end of the cylinder (51) fixedly connected to the end face of the closed cover (52).