TWM456392U - Solar energy luminous brick wall - Google Patents

Description

Solar light brick wall

The present invention relates to a solar-powered brick wall, and more particularly to a solar-powered brick wall that can be used as a glass wall of a building.

Generally, buildings will be provided with transparent glass walls or glass curtains to enhance the light entering the room to achieve good lighting and beautification. Some commercial buildings or department stores will use glass walls to enhance the overall artistic sense of the building. To highlight its characteristics and attract customers. Although the glass wall already has the above advantages, the glass wall of the building cannot be changed after its construction. It is relatively monotonous and unchanged. Over time, it will lose its attraction and cause customers to lose. Therefore, the design of the glass wall is known. Still needs improvement.

Accordingly, it is an object of the present invention to provide a solar-emitting brick wall that is powered by solar energy and that can be illuminated to form an arbitrary pattern.

Thus, the novel solar light-emitting brick wall comprises: a plurality of solar light-emitting brick units, and a controller.

The solar light-emitting brick units are arranged next to each other, and each solar light-emitting brick unit comprises: a brick body and at least one photoelectric conversion module. And at least one lighting module. The brick body has a first surface for allowing light to enter and exit, a second surface opposite to the first surface, and a plurality of connected to each other and respectively connected between the first surface and the second surface a side surface for allowing light to enter and exit, the brick body reflecting light passing through the first surface toward the side surfaces, and reflecting light passing through the side surfaces toward the first surface . The photoelectric conversion module is disposed on one of the side surfaces. The light emitting module is disposed on the other of the side surfaces and electrically connected to the photoelectric conversion module and can be driven by the electric power generated by the photoelectric conversion module to emit light, and the light generated by the light emitting module can be corresponding thereto The side surface of the brick body is ejected through the first side of the brick body. The controller is electrically connected to the photoelectric conversion module and the light-emitting module of each solar light-emitting brick unit, and the controller can control the power provided by the photoelectric conversion module of each solar light-emitting brick unit to the light-emitting module to control the light-emitting The module emits light.

The utility model has the advantages that: the solar light-emitting brick units are arranged into a wall surface, and the controller can control the illumination of the light-emitting module of any one of the solar light-emitting brick units, so that the novel solar-emitting brick wall can emit light and change various patterns. To achieve the effect of advertising and beautifying the building, in addition, the photoelectric conversion module can provide the power of the new luminous operation, so that the novel does not need additional power consumption.

2‧‧‧Solar light brick unit

3‧‧‧Brick body

31‧‧‧Light guide plate

311‧‧‧ second side

32‧‧‧Diffusion layer

321‧‧‧ first side

331‧‧‧ side surface

33‧‧‧Diffuser

34‧‧‧ scattering particles

4‧‧‧ photoelectric conversion module

5‧‧‧Lighting module

51‧‧‧Installation board

52‧‧‧LED lights

6‧‧‧Front frame

7‧‧‧Battery

8‧‧‧ Controller

Other features and effects of the present invention will be apparent from the following description of the drawings, wherein: FIG. 1 is a schematic diagram showing several solar illuminations of a first preferred embodiment of the novel solar-emitting brick wall. Brick units are arranged in a wall surface; Figure 2 is an exploded perspective view showing the component correspondence of one of the solar light-emitting brick units of the first preferred embodiment; Figure 3 is a cross-sectional view of the first preferred embodiment, And a first surface of the solar light-emitting brick unit enters a traveling path after the brick body; FIG. 4 is a cross-sectional view of the first preferred embodiment, and simultaneously illustrates two of the solar light-emitting brick units Figure 5 is a cross-sectional view of a second preferred embodiment of the solar-powered brick wall of the present invention, and illustrates a first light source from one of the plurality of solar light-emitting brick units. The traveling path after the surface enters a brick body; and FIG. 6 is a cross-sectional view of the second preferred embodiment, and illustrates the traveling path of the light emitted by the two light emitting modules of one of the solar light-emitting brick units.

Before the present invention is described in detail, it should be noted that in the following description, similar elements are denoted by the same reference numerals.

Referring to Figures 1 to 4, a first preferred embodiment of the novel solar-emitting brick wall comprises: a plurality of solar light-emitting brick units 2, and a controller 8. The solar light-emitting brick units 2 are arranged adjacent to each other and stacked into a wall surface, which can be used to replace the glass wall of the traditional building. In this embodiment, the number of the solar light-emitting brick units 2 is exemplified by nine, but the implementation is not limited to nine, and may be determined according to the wall size of the glass wall required for the building. Every too The illuminating brick unit 2 comprises: a brick body 3, two photoelectric conversion modules 4, two illuminating modules 5, an outer frame 6, and a battery 7.

The brick body 3 is square and has a light guide plate 31 and a diffusion layer 32 on the surface of the light guide plate 31. The light guide plate 31 has a second surface 311 which may be made of acrylic, polycarbonate, polyethylene terephthalate, polyurethane, polyimide, rayon resin or glass. The diffusion layer 32 is located on a surface of the light guide plate 31 opposite to the second surface 311, and the diffusion layer 32 has a first surface 321 for allowing light to enter and exit. The diffusion layer 32 and the light guide plate 31 has four side surfaces 331 which are connected to each other and are respectively connected between the first surface 321 and the second surface 311 to allow light to enter and exit. The material of the diffusion layer 32 may be selected from the group consisting of acrylic, polycarbonate, polyethylene terephthalate, polyurethane, polyimide or rayon resin. In implementation, the material of the diffusion layer 32 may be selected from any of the above materials as a base material, and optical scattering particles (such as titanium dioxide) not shown may be added to enter the diffusion layer from the first surface 321 . The light of 32 can be reflected by the optical scattering particles to be emitted from the side surfaces 331. Conversely, the optical scattering particles located in the diffusion layer 32 can also direct the light passing through the side surfaces 331 toward the first surface. The direction of 321 is shot. Further, the light is diffused and atomized by the reflection effect of the scattering particles in the diffusion layer 32, so that the light emitted through the first surface 321 of the diffusion layer 32 is uniform. Another point is to say that the ray paths in Figures 3 and 4 are only illustrative and are not actual ray travel paths.

The photoelectric conversion modules 4 are respectively disposed on the two side surfaces 331 of the side surfaces 331 of the brick body 3 located on the upper and lower sides thereof. on. The photoelectric conversion modules 4 can respectively receive light that is incident on the first surface 321 from the outside and is incident on the side surfaces 331 corresponding thereto to generate electricity. The photoelectric conversion module 4 is a solar panel, such as a copper indium selenide (CIS) solar panel, a copper indium gallium selenide (CIGS) solar panel, a three-five semiconductor solar panel, and the like. In the present embodiment, the number of the photoelectric conversion modules 4 is two, but the number of the photoelectric conversion modules 4 may be three or four. Of course, the solar light-emitting brick unit 2 may also include only one photoelectric conversion module 4, It can be based on electricity consumption.

The light-emitting modules 5 are respectively disposed on the two side surfaces 331 of the side surfaces 331 of the brick body 3 which are located on the left and right sides. Each of the light-emitting modules 5 has a mounting plate 51 disposed on one side of the side surface 331 corresponding thereto, and a plurality of spaced-apart-arranged and respectively disposed on the mounting plate 51 and facing the side surface corresponding thereto LED light 52 of 331. The light generated by the light-emitting modules 5 can be respectively emitted through the side surfaces 331 of the brick body 3 corresponding thereto and through the first surface 321 of the brick body 3. In the embodiment, the number and color of the LED lamps 52 are not limited, and may be changed according to the use requirements. The mounting board 51 may be a PCB board or a solar panel. If a solar panel is used, the overall power generation amount can be improved. In addition, the number of the light-emitting modules 5 is two, but the number of the light-emitting modules 5 may be three or four. Of course, the solar light-emitting brick unit 2 may include only one light-emitting module 5 as long as the brightness reaches a demand.

The outer frame 6 is wrapped around the brick body 3 and can accommodate the photoelectric conversion module 4 and the light emitting module 5 . The outer frame 6 of each solar light-emitting brick unit 2 can be connected to the outer frame 6 of another solar light-emitting brick unit 2, and Arrange and combine into a wall (Figure 1).

The battery 7 is electrically connected to the photoelectric conversion module 4 and the light-emitting modules 5, and the battery 7 can separately store the power generated by the photoelectric conversion modules 4 and supply the power to the light-emitting modules 5, In turn, the light-emitting modules 5 are driven to emit light. However, the present invention is not necessary to provide the battery 7 because the power generated by the photoelectric conversion modules 4 can be directly supplied to the light-emitting modules 5 as the power required for illumination by appropriate circuit design.

The controller 8 of the embodiment is electrically connected to the photoelectric conversion modules 4 of the solar light-emitting brick units 2 and the light-emitting modules 5 . The controller 8 can control the power provided by the photoelectric conversion modules 4 of each of the solar light-emitting brick units 2 to the light-emitting modules 5 to control the light-emitting modules 5 to emit light.

When the embodiment is used in the daytime, the light of the sun passes through the first surface 321 of the brick body 3 of each solar light-emitting brick unit 2, and the light incident on the first surface 321 passes through the diffusion layer 32 and the light guide plate. The light guiding function of 31 is guided to the side surfaces 331. Therefore, the photoelectric conversion modules 4 can convert the light rays emitted from the corresponding side surfaces 331 into electric power and store them in the battery 7.

When the embodiment is used at night, each solar light-emitting brick unit 2 can be controlled by the controller 8, so that the light-emitting modules 5 of each solar light-emitting brick unit 2 can be stored in the electric drive of the battery 7. And glow. The light emitted by the light-emitting modules 5 of each of the solar light-emitting brick units 2 that are driven to emit light can pass through the side surfaces of the brick body 3 corresponding thereto. The surface 331 emits light from the first surface 321 through the refraction and diffusion of the brick body 3. Therefore, each brick body 3 is formed into a light-emitting shape by the light of the light-emitting module 5. In actual implementation, the controller 8 can control any of the solar light-emitting brick units 2 to emit light, and the light-emitting shapes of the respective solar light-emitting brick units 2 are matched to form a pattern, such as a character, a symbol or an advertisement mark. Of course, as long as the brightness is sufficient, the present invention can also emit light and be arranged in a pattern when used during the day.

In summary, the present invention utilizes the solar light-emitting brick units 2 to be stacked on each other to form a wall surface, and the light-emitting modules 5 of any one of the solar light-emitting brick units 2 can be driven and illuminated by the controller 8, so that the present invention Solar-powered brick walls can illuminate and change various patterns to serve as an advertising sign for buildings. Moreover, through the design of the material and structure of the brick body 3 of each solar light-emitting brick unit 2, the uniformity of light emitted from the first surface 321 of the brick body 32 can be increased, and the light emitted by the present invention is softened. In addition, the power generated by the photoelectric conversion modules 4 during the day can be stored in the battery 7 for use by the solar light-emitting brick units 2 at night, so that the present invention does not require additional power consumption, thereby achieving environmental protection and energy saving effects.

Referring to FIGS. 5 and 6, a second preferred embodiment of the solar illuminating brick wall of the present invention is substantially the same as the first preferred embodiment. The difference is that the brick body 3 of each solar illuminating brick unit 2 has only one Square diffuser plate 33. The diffuser plate 33 has the first surface 321 , the second surface 311 , and the side surfaces 331 . The material of the diffusion plate 33 is the same as that of the diffusion layer 32 of the first preferred embodiment, but the thickness thereof is thick, and preferably the diffusion plate 33 is also added with scattering particles 34 to pass through the first surface 321 . The light can be The side surfaces 331 are emitted, and conversely, light rays passing through the side surfaces 331 can be emitted toward the first surface 321 . Moreover, the ray paths in Figures 5 and 6 are only illustrative and are not actual ray travel paths. The remaining functions of the embodiment are the same as those of the first preferred embodiment, and are not described herein again.

However, the above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, that is, the simple equivalent changes and modifications made in accordance with the scope of the present patent application and the contents of the patent specification, All remain within the scope of this new patent.

2‧‧‧Solar light brick unit

3‧‧‧Brick body

6‧‧‧Front frame

8‧‧‧ Controller

Claims (8)

A solar light-emitting brick wall comprising: a plurality of solar light-emitting brick units arranged adjacent to each other, each solar light-emitting brick unit comprising: a brick body having a first surface for allowing light to enter and exit, and opposite to the first a second side of one side, and a plurality of side surfaces connected to each other and respectively connected between the first surface and the second surface for allowing light to enter and exit, the brick body may pass through the first surface The light rays are reflected toward the side surfaces, and light rays passing through the side surfaces are reflected toward the first surface; at least one photoelectric conversion module is disposed on one of the side surfaces; at least one light is emitted a module disposed on the other of the side surfaces and electrically connected to the photoelectric conversion module and capable of being driven by the electric power generated by the photoelectric conversion module, and the light generated by the illumination module can pass through The side surface of the brick body is emitted through the first surface of the brick body; and a controller electrically connects the photoelectric conversion module and the light emitting module of each solar light-emitting brick unit, and the controller can control each solar energy The photoelectric conversion module unit to the light-tile power of the light emitting module, to control the light-emitting module to emit light. The solar-emitting brick wall of claim 1, wherein the controller controls the light-emitting modules of the solar-emitting brick units to emit light and be arranged in a pattern. The solar-emitting brick wall of claim 2, wherein the pattern is a text, a symbol or an advertising sign. The solar light-emitting brick wall of claim 1, wherein the brick body of each solar light-emitting brick unit has a light guide plate having the second surface, and a surface of the light guide plate opposite to the second surface And having a diffusion layer of the first surface, the diffusion layer and the light guide plate have the side surfaces. The solar light-emitting brick wall of claim 1, wherein the brick body of each solar light-emitting brick unit has a diffusing plate having the first surface, the second surface, and the side surfaces. The solar light-emitting brick wall of claim 1, wherein each of the solar light-emitting brick units further comprises an outer frame surrounding the brick body and accommodating the photoelectric conversion module and the light-emitting module. The solar illuminating brick wall of claim 1, wherein each of the solar illuminating brick units further comprises a battery electrically connected to the photoelectric conversion module and the illuminating module and capable of storing electric power generated by the photoelectric conversion module. The solar light-emitting brick wall according to claim 1, wherein the light-emitting module of each solar light-emitting brick unit has a setting opposite thereto A mounting plate on one side of the side surface of the brick body, and a plurality of LED lamps arranged at a distance from each other and disposed on the mounting plate and facing the brick body.