RU184527U1 - Lighting device - Google Patents

Abstract

The utility model relates to the field of household lighting devices, namely to devices for lighting residential and non-residential premises that do not have windows (basements, corridors, hallways, bathrooms and toilets, as well as mines, mines, pools, aquariums, etc. ). The technical task of the proposed utility model is to increase the luminous flux entering the illuminated room and to improve the comfort of people staying in the room. The technical result is achieved by the fact that the lighting device containing the fiber optic cable a screening lens, a fixed curved cylindrical plano-convex focusing lens placed in a mirror housing, which is mounted on the solar wall of the house with a bracket, the convex base of the transparent focusing funnel in the form of a truncated cone is placed in the focus of the lens, the top of the funnel is connected to the input end of the optical fiber cable, and the output the end of the cable is located in a dark room, and at its end there is a diffusing lens that evenly distributes the light flux, around the focusing lens are located guide mirror, directing the flow of light on the focusing mirror positioned in front of the focusing lens. Fig. 1

Description

The utility model relates to the field of household lighting devices, namely to devices for lighting residential and non-residential premises that do not have windows (basements, corridors, hallways, bathrooms and toilets, as well as mines, mines, pools, aquariums, etc. )

Well-known lighting devices - electric lamps, have significant disadvantages: relatively high energy consumption, electrical and fire hazard, the need for their constant on and off, as well as the need to replace the lamps during their combustion due to their short life.

Currently, architects, when solving lighting issues, are increasingly trying to use natural light. One of such solutions is anti-aircraft lights - transparent transparent structures in the roof of the building. Anti-aircraft lights can be installed on the roof of any shape, thereby eliminating the lack of natural lighting of the room, (http://fb.ru/article/330558/zenitnvie-fonari-promyishlennyih-zdaniy-dlya-ekonomii-elektroenergii-vidyi-osobennosti viewed 10.12. 2017).

However, the disadvantage of anti-aircraft lights is that they are limited in use, i.e. can only be installed on the upper floors of buildings.

Another promising area in modern lighting technology is fiber optic and hollow fibers. This type of lighting is also an example of modern energy-saving technologies. The light coming from the source enters the input end of the fiber and, due to internal reflection, passes through its channel and exits the output end. The absence of electric current in the fiber (and, consequently, the lack of heating) of the fiber optic lighting device gives it some advantages over other types. This feature allows the use of such lighting when illuminating pools, aquariums and rooms with high humidity. In addition, fiber optic fibers are easy to install. However, the main advantage of fiber optic lighting is its efficiency. After all, a halogen lamp, which in this case serves as a light source, is capable of converting electrical energy into light energy almost without loss.

(http://www.krovlimssia.ru/rubriki/materialy-itexnologii/svetovody/klassifikaciya-polyx-svetovodov viewed 12/10/2017)

The disadvantage of fiber optic and hollow optical fibers is that it is impossible to use them for proper lighting of a room.

The closest analogue is a solar fiber-optic lighting device containing a fiber optic cable and a fixed curved cylindrical plano-convex focusing lens placed in a mirrored housing, which is attached to the solar wall of the house with a bracket, and the convex base of the transparent focusing funnel in the form of a truncated cone is placed at the focus of the lens the funnel is connected to the input end of the fiber optic cable, and the output end of the cable is in a dark room and there is a p sseivayuschaya lens evenly distributes light flux. (RF patent No. 102 747, IPC F21S 11/00, F21V 33/00, SOLAR FIBER OPTIC LIGHTING DEVICE, publ. 03/10/2011)

The disadvantage of this device is that the amount of light flux depends on the size of the lens, which limits the number of light rays entering the illuminated room and the comfort of people in the room.

The technical task of the proposed utility model is to increase the luminous flux entering the illuminated room.

The technical result is achieved by the fact that a lighting device containing a fiber optic cable, a diffusing lens, a fixed curved cylindrical plano-convex focusing lens placed in a mirrored housing, which is designed to be mounted on the solar wall of the house with a bracket, the convex base of the transparent focusing funnel in the form of a lens is placed truncated cone, the top of the funnel is connected to the input end of the fiber optic cable, and the output end of the cable is designed to be located in t At the end of the room and at its end there is a scattering lens that evenly distributes the light flux, focusing lenses are located in front of the focusing lens, redirecting mirrors that reflect light rays to the focusing mirrors, configured so that the reflected light rays fall on the focusing lenses.

A diagram of the lighting device is shown in FIG. one.

The lighting device consists of a plano-convex cylindrical focusing lens 1, a mirror housing 2, redirecting 9 and focusing mirrors 8, a cylindrical transparent focusing funnel 3, is fixed with an arm 4 on the south (solar) wall of the house 10. The convex base of the conical funnel 3 made of transparent material in the form of a truncated cone, aligned with the focus area of a plano-convex cylindrical focusing lens 1, and the apex aligned with the input end of the optical fiber cable 5. Light through the optical fibers the cable 5 enters the scattering sphere 6 and evenly distributed, illuminates the illuminated room 11.

The lighting device works as follows: the focusing unit of the device, consisting of a plano-convex focusing lens 1, housing 2 and a cylindrical transparent funnel 3, is fixed using an arm 4 on the south (solar) wall of the house 10, and is oriented towards the sun in azimuth and elevation (like satellite dish antenna). The plano-convex focusing lens 1 must have a special shape resembling a side slice of a toroid so that when the position of the sun in the sky changes during the day, the focal area on which the sun's rays are concentrated does not move 7. The convex base of the conical funnel 3, made of transparent material in the form of a truncated cone, combined with the focal area of the lens, and the apex aligned with the input end of the optical fiber cable 5. The light flux, and due to the redirecting 9 and focusing mirrors 8, the light flux increases Then, it enters the base of the funnel 3, passes through it, tapering to the size of the end of the fiber optic cable 5. Then the light enters the scattering sphere 6 through the cable and evenly distributed illuminates the illuminated room 11. To increase the directed light flux to the focusing lens 1, around it redirecting mirrors 9 are placed, a reflected light flux that passes by the focusing lens 1 (i.e. does not fall on it), redirecting mirrors 9 reflect light rays onto focusing mirrors 8. Focusing mirrors 8 so that the reflected light rays 7 hit the focusing lens 1. This can significantly increase the amount of light passing through the focusing lens 1, the fiber optic cable 5 and entering the scattering sphere 6. Thus, sunlight is transported into the illuminated room 11 without any or conversion to other forms of energy. The device does not consume electricity at all, which ensures its high efficiency.

Claims (1)

A lighting device containing a fiber optic cable, a diffusing lens, a fixed curved cylindrical plano-convex focusing lens placed in a mirror housing that is designed to be mounted on the solar wall of the house with a bracket, the convex base of the transparent focusing funnel in the form of a truncated cone, the top of the funnel connected to the input end of the fiber optic cable, and the output end of the cable is designed to be located in a dark room, and at its end there is a eivayuschaya lens, uniformly distributing the light flux, characterized in that, before the focusing lens focusing mirror positioned, and around the focus lens - redirecting mirror reflecting light rays to the focusing mirror are configured so that the reflected light rays fall on the focusing lens.

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