CN210891429U - Optical energy transmission system - Google Patents

Abstract

The utility model provides a light energy transmission system, it including: indoor fixed plate, indoor light source spare, outdoor fixed plate, outdoor light source spare and leaded light optic fibre. The indoor fixing plate is used for being fixed on the inner wall of the building, and the outdoor fixing plate is used for being fixed on the outer wall of the building. The indoor light source part has light collecting and scattering functions, and is fixed on the indoor fixing plate. The outdoor light source part has light collecting and diffusing functions, and the indoor light source part is fixed on the outdoor fixing plate. The indoor light source part and the outdoor light source part carry out light energy transmission through the light guide optical fiber. Indoor outer luminous energy can mutual transmission through leaded light optic fibre for outside natural light can conduct to indoor being used for the illumination, and inside illumination light can conduct to outdoor being used for the illumination, thereby has improved the utilization ratio of luminous energy, has reduced the energy consumption extravagant.

Description

Optical energy transmission system

Technical Field

The utility model relates to a light energy transmission system.

Background

With the rapid development of society, non-renewable energy sources are continuously consumed, and energy conservation and environmental protection become common global endeavor targets. In some buildings, there are dark rooms without direct natural lighting, so that only artificial lighting can be used, thereby increasing the energy consumption of the building. On the other hand, in addition to the illumination inside the building, the illumination outside the building is often required due to the need of the city image, and the illumination systems of the two are usually independent, so that the illumination energy consumption of the building is increased invisibly. The current indoor lighting technology has the advantages that natural light is introduced through optical fibers to illuminate, but the exterior of a building is illuminated through a floodlight and the like. This has the disadvantage that the optical fiber will not function at night, but the external light fixture requires additional energy consumption.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a light energy transmission system in order to overcome the unable defect that is used for the external illumination of indoor illumination light among the prior art.

The utility model discloses an above-mentioned technical problem is solved through following technical scheme:

an optical energy transmission system, comprising:

the indoor fixing plate is used for being fixed on the building inner wall;

the indoor light source part has the functions of light collection and light scattering, and is fixed on the indoor fixing plate;

the outdoor fixing plate is used for being fixed on an outer wall of a building;

the outdoor light source part has light collecting and diffusing functions and is fixed on the outdoor fixing plate;

and the indoor light source part and the outdoor light source part carry out light energy transmission through the light guide optical fiber.

Preferably, the light energy transmission system further includes an indoor transparent plate, the indoor transparent plate is fixed to the indoor fixing plate, and the indoor light source is located between the indoor transparent plate and the indoor fixing plate.

Preferably, the indoor light source element is provided with a light port for collecting and diffusing light, and the light port is opposite to the indoor light-transmitting plate.

Preferably, the indoor light-transmitting plate is a frosted light-transmitting material.

Preferably, the light energy transmission system further comprises an indoor LED lamp, and the indoor LED lamp is fixed to the indoor fixing plate and located between the indoor transparent plate and the indoor fixing plate.

Preferably, the light energy transmission system further comprises a controller and an optical sensor for detecting brightness, the controller is electrically connected with the optical sensor and the indoor LED lamp respectively, and the controller is used for controlling the indoor LED lamp to be turned on or turned off.

Preferably, the number of the indoor light source, the outdoor light source and the light guide fiber is multiple and the same, the light energy transmission system further includes an indoor fiber integration plate, the indoor fiber integration plate is fixed to the indoor fixing plate, and one end of the light guide fiber located indoors is fixed to the indoor fiber integration plate.

Preferably, the light energy transmission system further includes an outdoor optical fiber integration plate, the outdoor optical fiber integration plate is fixed to the outdoor fixing plate, and one end of the light guide optical fiber located outdoors is fixed to the outdoor optical fiber integration plate.

Preferably, the optical energy transmission system further includes an outdoor transparent plate fixed to the outdoor fixing plate, and the outdoor light source is located between the outdoor transparent plate and the outdoor fixing plate.

Preferably, the outdoor light-transmitting plate is a frosted light-transmitting material.

On the basis of the common knowledge in the field, the above preferred conditions can be combined at will to obtain the preferred embodiments of the present invention.

The utility model discloses an actively advance the effect and lie in: indoor outer luminous energy can mutual transmission through leaded light optic fibre for outside natural light can conduct to indoor being used for the illumination, and inside illumination light can conduct to outdoor being used for the illumination, thereby has improved the utilization ratio of luminous energy, has reduced the energy consumption extravagant.

Drawings

Fig. 1 is a schematic perspective view of an outdoor portion of a light energy transmission system according to a preferred embodiment of the present invention.

Fig. 2 is a schematic view of the internal structure of the outdoor portion of the optical energy transmission system according to the preferred embodiment of the present invention.

Fig. 3 is a side view of the internal structure of the indoor portion of the optical energy transmission system in the preferred embodiment of the present invention.

Fig. 4 is a front view of the internal structure of the indoor portion of the optical energy transmission system in the preferred embodiment of the present invention.

Description of reference numerals:

indoor fixing plate 100

Indoor light source 110

Indoor light-transmitting panel 120

Indoor LED Lamp 130

Optical sensor 140

Indoor optical fiber integration board 150

Outdoor fixing plate 200

Outdoor light source 210

Outdoor optical fiber integration board 220

Outdoor light-transmitting panel 230

Light guide fiber 300

Detailed Description

The present invention will be more clearly and completely described below with reference to the accompanying drawings.

Fig. 1-4 illustrate an optical energy transmission system comprising: an indoor fixing plate 100, an indoor light source 110, an outdoor fixing plate 200, an outdoor light source 210, and a light guide fiber 300. The indoor fixing plate 100 is used to be fixed to the inner wall of the building, and the outdoor fixing plate 200 is used to be fixed to the outer wall of the building. The indoor light source 110 has light collecting and diffusing functions, and the indoor light source 110 is fixed to the indoor fixing plate 100. The outdoor light source 210 has light collecting and diffusing functions, and the outdoor light source 210 is fixed to the outdoor fixing plate 200. The indoor light source 110 and the outdoor light source 210 transmit light energy through the light guide fiber 300.

In this embodiment, when the external natural light is strong, the outdoor light source 210 can absorb the natural light and transmit the collected natural light to the indoor light source 110 through the light guide fiber 300, so that the indoor light source 110 emits light for indoor illumination. When the user is at night, the outdoor light source unit 210 located indoors can absorb indoor illumination light and conduct the collected illumination light to the outdoor light source unit 210 through the light guide fiber 300, so that the outdoor light source unit 210 emits light for outdoor illumination. Indoor outer light energy can mutual transmission through leaded light optic fibre 300 for make outside natural light can conduct to indoor being used for the illumination, inside illumination light can conduct to outdoor being used for the illumination, thereby has improved the utilization ratio of light energy, has reduced the energy consumption extravagant.

In this embodiment, the optical energy transmission system further includes an indoor light-transmitting panel 120. The indoor transparent plate 120 is fixed to the indoor fixing plate 100, and the indoor light source 110 is located between the indoor transparent plate 120 and the indoor fixing plate 100. The indoor light-transmitting plate 120 serves to protect the indoor light source element 110 while not affecting the transmission of light.

To improve the collection and dispersion of light energy, the indoor light source 110 has a light-collecting and light-dispersing opening (not shown), which faces the indoor transparent plate 120.

In addition, the indoor light-transmitting plate 120 is a frosted light-transmitting material. The light is diffused through the frosted light-transmitting material, the intensity is reduced, the light is soft, and the direct lighting and dazzling of the light are avoided.

As shown in fig. 3 and 4, when the light energy collected by the outdoor light source 210 cannot meet the brightness requirement of the indoor lighting, brightness can be supplemented by other light sources. The optical energy transmission system further includes an indoor LED lamp 130, and the indoor LED lamp 130 is fixed to the indoor fixing plate 100 and is located between the indoor transparent plate 120 and the indoor fixing plate 100.

Light rays emitted to the frosted light-transmitting material are subjected to diffuse reflection. When the night comes and the external brightness is insufficient, and the indoor LED lamp 130 illuminates indoors, the light emitted by the indoor LED lamp 130 can be reflected by the indoor transparent plate 120 to enter the indoor light source element 110, so as to provide the outdoor light source element 210 with light energy.

In order to implement the indoor automatic light supplement, the light energy transmission system further includes a controller (not shown in the figure) and an optical sensor 140 for detecting brightness, the controller is electrically connected to the optical sensor 140 and the indoor LED lamp 130, and the controller is used for controlling the indoor LED lamp 130 to be turned on or turned off. When the indoor brightness is insufficient, the optical sensor 140 sends a signal to the controller, and the controller controls the indoor LED lamp 130 to be turned on; when the indoor brightness is sufficient, the optical sensor 140 sends a signal to the controller, and the controller controls the indoor LED lamp 130 to turn off.

In addition, the indoor light source 110, the outdoor light source 210, and the light guide fiber 300 are plural and equal in number. The optical energy transmission system further includes an indoor optical fiber integration plate 150 and an outdoor optical fiber integration plate 220. The indoor optical fiber integration plate 150 is fixed to the indoor fixing plate 100, and one end of the light guide fiber 300 located indoors is fixed to the indoor optical fiber integration plate 150. The outdoor optical fiber integration plate 220 is fixed to the outdoor fixing plate 200, and one end of the light guide optical fiber 300 located outdoors is fixed to the outdoor optical fiber integration plate 220.

The indoor optical fiber integration plate 150 and the outdoor optical fiber integration plate 220 are mainly used for arranging and fixing the light guide optical fibers 300, so that the mutual crossing of the light guide optical fibers 300 is avoided, the searching and the maintenance are facilitated, and the appearance is neat and attractive.

The optical energy transmission system also includes an outdoor light-transmissive panel 230. The outdoor light-transmitting plate 230 is fixed to the outdoor fixing plate 200, and the outdoor light source 210 is located between the outdoor light-transmitting plate 230 and the outdoor fixing plate 200. The outdoor light-transmitting plate 230 serves to protect the outdoor light source unit 210 while not affecting the transmission of light.

The outdoor light-transmitting panel 230 is a frosted light-transmitting material. The light is diffused through the frosted light-transmitting material, the intensity is reduced, the light is soft, and the direct lighting and dazzling of the light are avoided.

In order to improve the collection and dispersion of the light energy, the outdoor light source 210 has a light-collecting and light-dispersing opening facing the outdoor transparent plate 230.

Although specific embodiments of the present invention have been described above, it will be understood by those skilled in the art that this is by way of example only and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and the principles of the present invention, and these changes and modifications are all within the scope of the present invention.

Claims (10)

1. An optical energy transmission system, comprising:

the indoor fixing plate is used for being fixed on the building inner wall;

the indoor light source part has the functions of light collection and light scattering, and is fixed on the indoor fixing plate;

the outdoor fixing plate is used for being fixed on an outer wall of a building;

the outdoor light source part has light collecting and diffusing functions and is fixed on the outdoor fixing plate;

and the indoor light source part and the outdoor light source part carry out light energy transmission through the light guide optical fiber.

2. The optical energy transmission system of claim 1, further comprising an indoor transparent plate fixed to the indoor fixing plate, wherein the indoor light source element is located between the indoor transparent plate and the indoor fixing plate.

3. The light energy transfer system of claim 2, wherein said indoor light source element has a light collecting and light dispersing light port, said light port facing said indoor light-transmitting plate.

4. The light energy transmission system of claim 3, wherein the indoor light-transmitting panel is a frosted light-transmitting material.

5. The optical energy transmission system of claim 4, further comprising an indoor LED lamp secured to the indoor mounting plate and positioned between the indoor light-transmissive plate and the indoor mounting plate.

6. The light energy transmission system of claim 5, further comprising a controller and an optical sensor for detecting brightness, wherein the controller is electrically connected to the optical sensor and the indoor LED lamp, respectively, and the controller is configured to control the indoor LED lamp to be turned on or off.

7. The optical energy transmission system according to claim 1, wherein the number of the indoor light source, the outdoor light source and the light guide fiber is plural and equal, the optical energy transmission system further comprises an indoor fiber integration plate, the indoor fiber integration plate is fixed to the indoor fixing plate, and one end of the light guide fiber located indoors is fixed to the indoor fiber integration plate.

8. The optical energy transmission system as claimed in claim 7, further comprising an outdoor optical fiber integration plate fixed to the outdoor fixing plate, wherein the end of the light guide fiber located outdoors is fixed to the outdoor optical fiber integration plate.

9. The optical energy transmission system of claim 1, further comprising an outdoor transparent plate fixed to the outdoor fixing plate, wherein the outdoor light source element is located between the outdoor transparent plate and the outdoor fixing plate.

10. The light energy transmission system of claim 9, wherein the outdoor optically transparent sheet is a frosted optically transparent material.

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