RS919U - LIGHTING PANO LOCATED BETWEEN TWO LAYERS OF THERMAL INSULATING GLASS - Google Patents

Abstract

Illuminated panel placed between two layers of insulating glass. The light-permeable sheet material (2) is inserted into the space between the two glass surfaces of the thermal insulating glass and is sealed by the method used to perform the classical manufacture of thermal insulating glass. The power supply of the light source (1) is by means of connectors or free conductors. The light-permeable plate material (2) is incised at the necessary places (3) to allow the light to refract and radiate into the surrounding space. To ensure safe heat dissipation, the radiator (5) is mounted on an aluminum profile (7) in a thermal insulation glass to obtain a larger cooling surface.

Description

Technical field

This invention belongs to the field of production of luminous panels, by means of light obtained by electric energy which illuminates the light-transmitting plate material laterally.

According to the International Classification of Patents, the invention belongs to MKP A 47 F11/06

<*>ll/06 = means for achieving special optical effects

<*>11/10 = devices with light sources

<*>F21 = field of electrical engineering

Technical problem

The invention solves the problem of placing a light panel between two layers of thermal insulating glass. Since illuminated billboards are mostly used for advertising purposes, this allows the utilization of hitherto unused advertising space.

Three-dimensional glass is considered to be a glass composed of two glass plates at a distance of 6 to 25 mm. The space between the plates and their connection is made with metal brackets that are filled with drying agents. The edge connection between the two layers of glass must achieve a perfect and long-lasting seal to prevent the entry of moist air. The space between the two panes is filled with air or some inert gas, depending on the production technology of thermal insulating glass.

State of the art

Most of the lighting panel solutions known so far have such constructive solutions that due to their excessive dimensions, it is impossible to place them in the space between two layers of thermal insulating glass.

Complicated manufacturing, high energy consumption, high power supply voltages, short lifetime of the light source, are the shortcomings present in the majority of existing solutions.

Description of the invention with a description of the drawings and examples of the invention

Exposition of the essence of the invention

The invention consists of a light-transmitting plate material (acrylic glass, ordinary glass, cast light-transmitting plate materials, etc.) which is located between two layers of thermal insulating glass. In the following text, we will call a panel made of light-transmitting panel material self-panel.

It is possible to engrave a text, picture, logo, sign, warning, notification, etc. on the board, which clearly show (usually advertise) a specific product, company, sign, and in general everything that needs to be exposed in a visible way.

The invention described in this application has the following multiple advantages compared to existing solutions, which are reflected in the following: - Durability and efficiency is much better compared to most solutions known so far.

- Electricity consumption is many times lower.

-Using low, human-safe voltage levels.

-Dimensions smaller than previously known solutions.

- It is possible to combine different colors of acrylic glass or other translucent materials in order to obtain better and more attractive light effects.

Brief description of the draft images

The invention is described in detail on the example of execution shown in the drawing:

Figure 1 - represents the principle view of the installation of the light source and the propagation of light through the plate placed between two layers of thermal insulating glass.

Figure 2 - shows one of the possible solutions for cooling the light source.

picture 3 - light sources ( ©2006 Philips Lumileds Lighting Companv)

Detailed description of the invention

The pictures show the principle way of distributing the light, as well as the heat dissipation and the dimensions of the light source (©2006 Philips Lumileds Lighting Companv).

Picture 1

In Figure 1, there is a representation and method of illumination of plate 2, which is cut by some mechanical method at place 3. The cut edges are at an angle of 45° so that the angle of light 6 coming out of the plate is 90° in relation to the plane of the thermal insulating glass 4.

Light sources 1 can be placed in the corners of plate 2, in order to obtain the largest and best distribution of light 6 inside plate 2. Of course, it is possible to place a larger number of light sources 1 on plate 2, and in different places depending on the technical ? and technological possibilities.

The light source 1 is placed vertically on the side surface of the plate 2, and as this type of light source does not heat up to temperatures that could damage the light-conducting material, i.e. plate 2, it is possible to place it directly, or even lean against the side edge of plate 2. As the size of the light source 1 itself is very small (dimensions, elevations and shape are given on Figure 3), by placing the light source 1 in this way, the effect is obtained that almost all the light flux 6 enters inside the plate 2. Due to the effect of the limiting angle of refraction of light when it needs to pass from a solid to a gaseous medium, almost the entire light flux 6 remains inside the plate 2, so plate 2 practically behaves like a light guide. Only when the light 6 encounters an obstacle that deflects it, so that it now falls on the boundary surface of the board and the external environment at a greater angle than the limiting angle of refraction of light for the type of material from which the board is made, it can leave the board 2 and become visible to the observer of the panel. This practically means that the plate 2 in places where there are no obstacles that deflect the light flux 6 is completely transparent and has the same basic feature as any other thermal insulating glass, which is that the observer can see what is behind the thermal insulating glass without any optical distortions. This obstacle 3 due to which the light leaves the plate can be mechanically etched. Cuts 3 of a geometrical shape like naSlld 1 have the best effect of radiating light, because the light after reflection from the wall of the cut channel 3 exits the plate 2 at an angle of 90° degrees. The path of channel 3 on board 2 also determines the luminous line, which the observer sees on board 2 and with which we write the desired message on the panel. Even small mechanical damage to the board such as rough sanding or shallow scoring such as writing with a sharp point on the acrylic board, give very visible luminous effects. A special effect is obtained when pieces of boards that are dyed in the desired colors with impurities in the material are glued to the plate that is illuminated. If the connection is the gluing between these two materials is well done (without trapped air between the plate and the glued plate with impurities), then the light 6 from plate 2 enters the glued plate with impurities without restriction introduced by the limiting angle of refraction of light. Then the admixtures in the plate material that is glued to the plate act as obstacles that emit light into the surrounding environment in only a certain color, i.e. in the color of these impurities. In practice, the light sources are mounted on a transparent acrylic glass plate, and the glued pieces are made of colored light-transmitting acrylic glass, and their shape determines the desired graphic message that we want to light up on the panel.

Picture 2

Figure 2 shows one of the possible solutions for mounting light sources and heat dissipation. Namely, the light sources 1 need heat dissipation (position 5 on Figure 1), where it is very important not to overheat the light source 1 (©2006 Philips Lumileds Lighting Companv), because the light and life characteristics of the light source 1 are reduced. In the way of heat dissipation shown on Figure 2, it is characteristic that when inserting the plate between two layers of thermal insulating glass, contact can be very easily made between the cooler 5 of the light source and already existing metal profiles 7 that are inside the thermal insulating glass and which are mentioned in the definition of thermal insulating glass. This ensures a much better transmission of the Light Source 1. Due to the fact that between the two layers of thermal insulating glass 4, light-permeable plate material 2 with heat sinks 5 and Light Sources 1 is placed, the total volume of gas inside the thermal insulating glass is reduced, as well as the increased heating of the metal profiles and the gas inside the thermal insulating glass, which makes it much easier to maintain low air humidity inside the thermal insulating glass, which is one of the main technological problems in the construction of the thermal insulating glass itself.

Picture 3

shows the cross-sections and dimensions, as well as the shapes of the ©2006 Philips Lumileds Lighting Companv light sources, which also have the following characteristics:

- very small dimensions

- work at temperatures up to 185 °C

- Industrial lighting performance > 140 lumens at 6500K white

- supply current up to 1500mA

- low thermal resistance up to 9 °C/W

- the best industrial sensitivity to moisture - level JEDEC 2a

- solder contacts compatible with the JEDEC 020c standard

- RoHS standard met

- meets the requirements of sterility according to JESD22 A_102

- easy and reliable maintenance - 50,000 hours of operation at lOOOmA with 70% illumination.

In the description, some information known in connection with ©2006 Philips Lumileds Lighting Company was used and published as such, and this invention does not refer to any invention or technical solution that is the property of the said company, but only for the purpose of explaining the invention shown here.

Method of industrial or other application of the invention:

Based on the above, the invention can be applied to any glazed surface with thermal insulating glass.

The most urgent applications are refrigerated showcases, showcases, windows, newsagents, outdoor illuminated advertisements, bibordl, means of transport and so on.

Claims (1)

1. The light panel placed between two layers of thermal insulating glass consists of a light-transmitting sheet material (2), a light source (1), thermal insulating glass (4), indicated by the fact that the plate (2) is made of light-transmitting material, which is lit from the side by a source of light (1), placed between two layers of thermal insulating glass (4), cut in the manner shown in Figure 1 so that the cut places on the light permeable plate They radiate light into the surrounding space, the shape of the cut path on the light permeable plate determines the luminous message that we want to write on the panel.