TWI667440B - Photoelectric light transmission scaffolding - Google Patents

Abstract

The invention relates to a photoelectric light-transmitting scaffold comprising a scaffold body, a plurality of shutters, a plurality of solar panels, and a reflecting device, wherein the shutter can transmit light and can be provided with a refractive surface, and the horizontal corresponding ground is arranged in parallel or oblique direction. At the top position of the main body of the scaffold; the solar panel is opposite to the two masks for receiving the light-receiving surface of the light, and the horizontally corresponding ground is disposed at the top end of the main body of the scaffold body in a parallel or oblique direction, and the two opposite light-receiving surfaces are respectively located at the upper and lower positions. The solar panel and the shutter form a roof of the main body of the scaffold; and the reflecting device is disposed in the main body of the scaffolding body corresponding to the position of the shutter and the solar panel, and can horizontally reflect the parallel or oblique direction of the ground to reflect the light below the solar panel. The light receiving surface or the folding; thereby, the invention can be lightly transmitted and has better solar power generation efficiency.

Description

Photoelectric light transmission scaffolding

The invention relates to a photoelectric transparent scaffold, which mainly relates to a scaffold which can be moderately transparent and has better solar power generation efficiency.

There is a shield above the scaffolding to block the external wind and rain from infiltrating into the room. In order to improve the green power generation effect, the solar panel can be placed above the shutter, and the sunlight can directly illuminate the solar panel to generate electricity. However, the top solar panel will cover the lower side. The shutters cause the sunlight to not penetrate into the room, resulting in insufficient light in the room.

When the plant is planted under the scaffold, the underlying light is insufficient due to the solar panel setting, and the light can provide a plant light source and perform photosynthesis, so that when the light is insufficient, the plant growth will be slowly lost.

It is an object of the present invention to provide a scaffold that is suitably light transmissive and has better solar power generation efficiency.

The invention comprises a scaffold main body, a plurality of louvers, a plurality of solar panels, and a reflecting device, wherein the louver is permeable to light, and the horizontally corresponding ground is disposed in a parallel or oblique direction at a top end of the scaffold body; and the solar panel is opposite to the second mask. The light-receiving surface of the light-receiving power is disposed at a top end of the main body of the scaffold body corresponding to the ground in a parallel or oblique direction, and the two opposite light-receiving surfaces are respectively located at the upper and lower positions, and the solar panel and the shutter form a roof of the main body of the scaffold; The reflecting device is disposed in the main body of the scaffold corresponding to the position below the shutter and the solar panel, and The horizontally corresponding ground surface expands the reflected light to the light receiving surface below the solar panel or collapses in a parallel or oblique direction.

Further, each of the shutters and each of the solar panels may be staggered, and the partial shutters and the partial solar panels may be staggered.

Further, the shielding plate can be provided with a refractive surface, and the refractive surface can be directly formed by the shielding plate or externally disposed on the shielding plate, and the external light can be projected downward through the shielding plate to be refracted by the refractive surface to have a uniform light diffusion effect.

Further, the reflecting device is connected with a control device, which has a pulling rope and a rotating shaft. The pulling rope is connected with the reflecting device, and one end of the pulling rope is connected with the rotating shaft, and the rotation of the rotating shaft can be controlled to drive the reflecting device to expand or close.

When the invention requires more light in the main body of the scaffold, the reflecting device can be folded, and the external sunlight can penetrate the shielding plate into the main body of the scaffold, and the average distribution of the shielding plate can provide the average illumination effect in the main body of the scaffolding body. And the planting body in the main body of the scaffold can provide a better growing environment, and the external sunlight can directly generate electricity by the light receiving surface above the solar panel, and can have both light transmission and power generation effects.

The invention can make the reflecting device be operated by the control device when the light requirement in the main body of the scaffold is low, and can be projected onto the reflecting device when the light enters the main body of the scaffold, and is reflected by the reflecting device to the light receiving surface below the solar panel. Therefore, the solar panel upper and lower light receiving surfaces can be simultaneously powered by light, and can have better power generation efficiency.

1‧‧‧ scaffold body

2‧‧‧ visor

21‧‧‧Refractive surface

3‧‧‧ solar panels

31‧‧‧Stained surface

32‧‧‧Stained surface

4‧‧‧Reflecting device

41‧‧‧Control device

411‧‧‧Drawstring

412‧‧‧ shaft

Figure 1 is a schematic view of a scaffold of the present invention.

Figure 2 is a schematic view showing the structure of the control device of the present invention.

Figure 3 is a schematic view showing the structure of another control device of the present invention.

FIG. 4 is a schematic view showing the light-receiving and power generation of the reflecting device in the present invention.

Figure 5 is a schematic view showing the power generation of the reflecting device in the present invention.

Fig. 6 is a schematic view showing the arrangement of the refracting surface of the shutter of the present invention.

Referring to Figures 1 to 4, the present invention includes a scaffold body 1, a number of shutters 2, a number of solar panels 3, and a reflecting device 4. The shutter 2 is transparent, and the material thereof can be made of PMMA acrylic, general glass or The other permeable material is manufactured, and the horizontally corresponding ground is disposed at a top end position of the scaffold body 1 in a parallel or oblique direction.

The solar panel 3 can be received by the light-receiving surface 31, 32 of the two masks, and the laterally corresponding ground surface is disposed at the top end of the scaffold body 1 in a parallel or oblique direction, and the two opposite light-receiving surfaces 31, 32 are respectively located at the upper and lower positions, and The solar panel 3 and the shutter 2 are coplanarly disposed to form a roof of the scaffold body 1, and as shown in the right side of the figure, each of the shutters 2 is interlaced with each of the solar panels 3, as shown in the left side of the figure. The partial louver 2 is shown interlaced with a portion of the solar panel 3, and the illuminating body 1 can have an average illumination effect, and the foregoing arrangement is exemplified and is not intended to limit the arrangement of the present invention.

The reflecting device 4 is disposed in the scaffold body 1 corresponding to the position below the shutter 2 and the solar panel 3, and can be unfolded or folded in a laterally parallel or oblique direction corresponding to the ground. The reflecting device 4 is a planar structure and can be a reflective cloth. The screen, the net body, the diaphragm, and the reflection, astigmatism and protection functions, and the reflection device 4 is connected with the control device 41, as shown in Fig. 2 and Fig. 3, the two types of the same function structure type, the control device 41 The pull cord 411 and the rotating shaft 412 are connected to the reflecting device 4, and one end of the pulling rope 411 is connected to the rotating shaft 412, and the rotating shaft 412 can be manually rotated. Turning or connecting a motor (not shown), and controlling the rotation of the rotating shaft 412 to drive the reflecting device 4 to expand or close.

In the present invention, when a large amount of light is required in the main body 1 of the scaffold, the reflecting device 4 can be folded as shown in FIG. 4, and the external sunlight can penetrate the shutter 2 into the main body 1 of the scaffold, and the visor 2 is evenly distributed. The setting can provide the average effect of illumination in the main body 1 of the scaffolding body, and the planting body 1 can provide a better growing environment when planting the plant, and the external sunlight can directly generate the light-receiving surface 31 above the solar panel 3 to generate electricity, and With light transmission and power generation.

When the light requirement in the main body 1 of the scaffold 1 can be low, the reflecting device 4 can be deployed by the control device 41 as shown in FIGS. 3 and 5, and the reflecting device 4 can be located below the corresponding shutter 2 and the solar panel 3. When the external light penetrates the shutter 2 into the scaffold body 1, it can be projected onto the reflecting device 4, and reflected by the reflecting device 4 to the light receiving surface 32 below the solar panel 3, so that the solar panel 3 receives the light above and below. The faces 31 and 32 can be simultaneously powered by light, which can have better power generation efficiency.

Referring to FIG. 6 , the structure is the same as that of FIG. 4 , and the difference is that the shielding plate 2 of the present invention can be provided with a refracting surface 21 that can diffuse light, and the refractive surface 21 can be integrally formed with the shielding plate 2 or added to the shielding plate. 2, and the external light is projected downward through the shutter 2 to be refracted by the refractive surface 21 to have a uniform light diffusion effect, and is more favorable for growth of plants (not shown) below the scaffold body 1.

It is to be noted that the present invention may have both light transmission and better power generation efficiency, and the foregoing embodiments are illustrative of the invention and are not intended to be limiting of the invention, and equivalent changes in accordance with the spirit of the invention also belong to the invention. Within the scope.

Claims (9)

The utility model relates to a photoelectric transparent scaffold comprising: a scaffolding body; a plurality of shielding plates, which are light-transmissive and laterally disposed at a top end of the scaffolding body; and a plurality of solar panels, the opposite two masks are capable of receiving light receiving surface of the light, and are laterally disposed on the Positioning the top end of the main body of the scaffolding body, and positioning the two opposite light receiving surfaces at upper and lower positions respectively, and the solar panel and the shielding plate form a roof of the main body of the scaffolding body; a reflecting device disposed in the main body of the scaffolding body should cover The plate and the position below the solar panel, and laterally expanding the reflected light to the light receiving surface or the bottom of the solar panel. The photovoltaic light-permeable scaffold of claim 1, wherein the shutter is made of PMMA acrylic or glass material. The photoelectrically transparent scaffold of claim 1, wherein the solar panel and the shutter are coplanar. The photoelectrically transparent scaffolding of claim 3, wherein each of the shutters is staggered with each of the solar panels. The photoelectrically transparent scaffold of claim 3, wherein the partial shutter is interlaced with the partial solar panel. The photoelectrically transparent scaffold of claim 1, wherein the reflecting device is a planar structure. The photoelectrically transparent scaffolding of claim 6, wherein the reflecting device is a reflective curtain or a mesh or a membrane. The photoelectric light-transmitting scaffold according to claim 1, wherein the reflecting device is connected with a control device, the control device has a pulling rope and a rotating shaft, and the pulling rope is connected with the reflecting device, and the pulling rope is The end is connected to the rotating shaft, and the rotation of the rotating shaft can be controlled to drive the reflecting device to expand or collapse. The photoelectrically transparent scaffold of claim 1, wherein the shutter is provided with a refractive surface that diffuses light.