AT500792A1 - GLASS ELEMENT WITH LIGHT FRAME - Google Patents

Description

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Qlaselemant with Uchtrahmen.

The invention relates to a glass element with a light frame based on 5 longitudinal light elements in the form of LED strips and / or EL strips and / or Langnaetheuchtstreifen or combinations of these light elements, Usually in modern glass constructions two or more 10 evenly or non-uniformly spaced Glass panes of flat glass, also referred to as float glass, used with a thickness of a few mm to about 21 mm, typically of 4 mm thickness and 16 mm spacing. The embodiments may be redesigned according to the characteristics of the weather protection, the sunscreen, the optical and design requirements, the sound insulation, the fire protection, the persons and property protection and the like. It is also possible to use combinations of the mentioned types.

A typical flat glass dimension is for example 6.00 x 3.21 meters 20 and from these the panes are produced for typical multi-pane insulating glass structures. By the edge bond hermetically sealed spaces are produced, which are usually filled by a noble gas. The Gasdruek is set according to the barometric air pressure at the place and at the time of production 25. Thus, at the time of production, there is a balance between the pressure in the vitrification chamber and the external barometric pressure in the production environment.

In addition to these single, triple, or even multiple float glass simple laiviarglaa superstructures, such multi-plate insulating glass superstructures may also be formed of slices based on I A < 1IT 1 β. S J r c * r »/ mr \ TD 771 C 1

Have a coating on one or both sides and thus influence the reflection and / or transmission and / or optical training in desired wavelength ranges of the light, the individual slices can be made to be prestressed or through-dyed or can be formed from so-called safety glass.

Bel safety glass or glass is concerned with glazes originally developed for the automotive industry for vehicle glazing, and such safety glass elements, which are sandwiched 10, are increasingly used in building technology today. Basically, a distinction is made between Einшheiben-Slcherheitsglae and laminated safety glass and it can be used in principle in the present invention, both types. No. 15,365,347 describes a lit transparent or semitransparent optical medium in the form of an acrylic plate, with two fluorescent tubes separating the light into the acrylic plate on two opposite sides.

By various surface designs or by several 20 layered plates Llchtauelenkung is effected to one side

This technique has been found to provide backlighting for flat panel displays and the use of very thin cold cathode ray tubes as a very useful illumination, particularly with white color emission 26. However, none of the present invention will

Fluorescent tubes or cold cathode ray tubes used.

In EP 0 516 514 an illuminated display panel is described. The illumination takes place with distributed light-emitting electronic components. The light sources are connected to a battery and electronic control. However, a glass element with a light frame is missing. ifiir tm

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In DE28603225U1 a light shade is described, in which one or more disc edges are provided with lighting means whose light is fed into the disc above the edge. As light sources S groupwise interconnected light-emitting diodes are called.

EP 0 821 820 B1 describes a lighting device with a body of transparent material, for example made of acrylic glass, and one or more band-shaped light sources. Ala band-shaped 10 light sources are called band-shaped printed circuit boards, on which light-emitting diodes In SMD technology are applied in dense, compact sequence. Further, ribbon-shaped light sources of electroluminescent foil, which continuously produce light over its length, are shown.

There, however, no longitudinal light element is described in a profile frame with a glass element.

In US 5,388,853 an illuminated display panel of licbtleitendem material is described in the form of acrylic glass. A light source on the lower side of the acrylic panel causes light to enter and a graphic design is made with laser in the acrylic panel. Also in this invention, no longitudinal light element is shown in a profile frame with a glaeeiement

The invention is therefore the object of developing a light-emitting element 25 so that it can be produced more cheaply and used with better light output.

A preferred embodiment of the invention relates to a glass element with a Uchtrahmen having at least one 30 Liohtelement longitudinal element in the form of an LED strip and / or EL-Streifena and / or Langnechleuchtstreifene. · · · · · · · · · «··· s

The invention also provides combinations of these light elements for use as a decorative element and / or lightning element in interior and / or exterior facades of buildings, interior furnishings and in vehicles and in the advertising industry and the like applications 5.

According to the invention, the invention relates to a glass element with a Uchtrahmen with at least one longitudinal light element in the form of an LED Strelfens and / or EL strip and / or Langnaehleuchtstreifens. 10

A typical safety glass structure consists of two float glass or Gusaglae disks with a thin inner layer or several thin inner layers of a total thickness of a few 0.1 mm and typically 0.4 mm or 0.8 mm thickness of Poly-vinyl-butyral (PVB). or polyurethanes (PU) or polyvinyl chlorides (PVC) or similar polymers or in cast form with preferably casting resins based on polyester or polyacrylic with corresponding Llchtbrechungslndlces greater than 1 and less than 2, typically in the range of 1.5 and / or ln the combination on glass panes in combination with 20 transparent plastic discs.

According to the invention, at least one longitudinal light element is preferably fastened on the inside of the frame, which serves as a spacer and is produced in the form of a profile. The attachment can be done with 26 self-adhesive tape or hot melt adhesive system or by snapping or screwing or crimping or crimping or insertion and the like Befestigungsmethodsn.

It must be taken into account the different coefficients of expansion of the frame 30 and the various light element in Bstrlsb. Usual frames are extruded from aluminum or various aluminum alloys. Basically, however, 6 e • a • • • • • 1 • s • • • • • • • • e • • • • • • • • • •

Plastics find use. In special designs, stainless steel frames or frames made of simple profiled iron sheets with a corresponding coating can be used. When using metallic frames, the good heat-dissipating effect and the good water-vapor barrier function are an advantage in the use of electroluminescent-sheet and long-luminescent-layer lighting elements.

A first embodiment of the invention will be described in terms of an EL strategy 10:

Longitudinal electroluminescent (EL) strips are preferably used with widths from 6.35 mm to 609.6 mm and a typical strip thickness of about 0.3 mm with lengths of 90 to 100 meters. 15 förden Installation in typical Isollarglaaaufbauten suitable strip widths of 12.7 mm and 25.4 mm very well. Operation takes place via so-called EL inverters. In this case, DC voltages of some 1.2 to 9 or 12 or 24 or 48 volts are usually transformed into alternating voltages of a few 20 100 volts to over 200 volts and frequencies of a few 50 Hz to a few kHz, typically 400 to 2,000 Hz. Inverters of this kind can now be arranged in the interior of the frame, in the frame profile or outside. In addition to these flat EL strips, in principle, longitudinal round EL elements can also be used.

The major disadvantage of such EL elements in conventional use is the short half-life of a few 1,000 to 2,500 and 3,000 hours. 30 half-life is understood to mean the Halllgkelwabnahme to half of the Initialhalligkeit. 7 e ···········

Even if standard EL films do not lift a direct end of life, the brightness of the emission decreases continuously due to the degradation of the electroluminescent and mostly micro-concealed electroluminophor. Degradation usually only occurs during operation and is significantly accelerated by high air humidity combined with increased temperature. Conventional polymeric laminates exhibit a marked increase in water vapor permeability when the temperature is increased. For typical 10 insulating glass structures, however, lifetime values of some 20 years at relatively high temperatures have to be guaranteed.

In accordance with the invention, insulating glass structures with an interior which is preferably approximately free from waverderhem offer an inert gas which is filled with inert gas, for example argon or krypton or similar gas mixtures. The water barrier is a water vapor barrier for EL elements.

In addition, usually a drying agent, or a so-called molecular sieve, is placed in the cavity of the Rahmenproflls and 20 of the frame profile is provided with openings to the interior, so that therein Wasserdampffeate be bound in the interior of a Isolierglasaufbaues. In addition, the frame rotates with the glass sheets with a polymer composition based on polyvinyl butanol (PVB), silicone, polyurethane (PU). Polyethersulfone (PES), Polyaulfone (P8U) and the like sealed. 25

By arranging such EL strips inside a Isolierglasaufbaues far longer half-lives can be achieved with careful implementation of the electrical connections. In addition, when using conventional float glaziers and / or casting glasses, UV-B filtering is provided, which leads to a reduction in the aging of the zinc sulfide plates 30

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Elektroluminophor "leads and thus also bets outdoor applications extended the general life, or the Emisslonhelligkeft increases over the time axis S A second embodiment of the invention is described in the form of an LED strip:

According Erflndungagemäß so-called LED Stroifen be used as a light element In frame for glass elements. In principle, all types 10 of LED elements can be used to produce a longitudinal LED strip. In addition to conventional LED elements with radial connections and in plastic housings as well as in Metallgehflusen also conventionally mounted on printed circuit substrates or shaded elements can be used. 15

Furthermore, surface-mountable LED1 *, so-called SMD (Surface Mount Device) or SMT (Surface Mount Technology) LED elements or electro-luminescent semiconductor element · Used in direct mounting on wiring substrates, ie untimely LEDs for the so-called Chlp-on-20 board technology.

In the COB method, both flexible or rigid or semiflexible printed circuit board materials can be used as substrates. Likewise, so-called lead frames, ie metallic stamped parts in strip form, with 25 lens elements and Halteelemante are carried out here by means of Inmould-Sprftzguß. Typical SMT LED components typically have a luminous intensity of 5 to 20 mCd at 20 mA and about 2 Voü-DC. Dia Luminous intensity is the current related to the solid angle, and SMT LEDs with relatively large green areas are generated. 9 9 e ee ee ee ee e e • e e e • e e • e e e e e e e e e e e e e e e e

Thus, such surface mount components have a component height of 2.1 mm to 0.8 mm and are readily available in a custom mounting frame with a height of 0.55 mm. s

Highlevel LED's with a beam angle of some 5 to 30 * already provide light intensities in the range of 25,000 mCd and in impulse operation you beyond. The dissipation of the heat loss and the type of contacting already present a significant problem 10 with such light intensities. For the use of the usual long service life of a few 10,000 to 100,000 hours, this problem must be solved. In the present Pall are available to dissipate the heat of the frame profiles, which are preferably made of aluminum. In such cases, the wiring substrates must be thermally well conductively mounted on the frame profile. It is also possible to prepare the twisting substrates on the basis of appropriate aluminum * printed circuit board material. Not only are the common red and green and yellow and blue signal colors of interest for a number of applications, but wild white light is also preferred. Such LEDs are operated Obllcherwelse in the bleu range. By fsrbkonvertlerende bodies a white emission is generated. Inorganic additions are used in the polymer matrix of the main body and thus extremely long-term emission spectra are achieved without color shifts 25

In addition, there is still the possibility of using so-called R-G-B LED's, that is LED's with 4 electrical connection elements and the Emissioniflarben red - green - blue, Bai such LED elements Although the electronic circuitry is complex, but it can be electronically eireugt and readjusted all mixed colors. Depending on the design of the electronic control unit, different color effects can also occur in FIG. 30

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LED strelves are fabricated on double-sided, flexible printed circuit boards with 5 SMD surface-mounted LEDs and other components based on roll-to-roll placement and bonding methods and in breadth of convenience. Usual roll lengths are 100 or 200 meters and above. Preferably, a plurality of LED elements are connected in series and can be operated, for example, with a Versoigungsepannung of 12 or 24 10 volts DC of such a unit.

By way of example, an LED strip of the company Osram Opto Semiconductor »with the type designation UNEARIIght Hex OS-LM11A is used. Such a LED strip is supplied with a total length of 8.4 m and a base of 10 LED's * 15 with a length of 140 mm with a height of less than 3 mm and a strip width of 10 mm. The back side of this LED-Strelfen is self-adhesive,

The power supply is 24 volts DC, with nominally the smallest unit to be operated of 10 LED's with 140 mm length depending on the 20 emisslonsfarbc between 40 and 50 mA needed Nominal is a light intensity of 95 mcd (blue) bla 305 mcd (white) and 730 mcd (yellow) causes. The power consumption of the 10 LED's is 0.96 to 1.2 watts or 8.9 to 8.6 watts per meter. The beam angle of these LED components is 120 ".

The operation of example 1 to 10 LED Laufmetem can therefore be done very well by inexpensive and simple power supplies and it is to pay attention to any Doppelieolationsvorschrift. 11 11 ·· «• · · · i • ·

The beam angle can be adapted to the particular application and asymmetrical emission characteristics can be achieved with special lens designs and / or presets. Furthermore, it may be advantageous to install a diffuser. In the present case, this can be achieved very easily in the interior of the isolating membrane element by means of transparent elements with a well-light-emitting and scattering surface.

As a substrate for such LED Strelfen one-sided and double-sided flexible printed circuit boards based on, for example, polyamides (PI) and / or 10 Polyethylenterephthelat (PET) or Poly Ethyiengiykol ·

Terephthalate (short name PETP or PET) and / or polyethersulfone (PES) and / or Polyetherlmid (PEI) and / or polyetheretherketone (PEEK) and / or Aramld and / or fiber-containing flexible films and the like may be used. In this case, thin copper foils and / or aluminum foils 13 are applied and patterned according to the wiring requirements.

This can be done by the usual in Leitsrplattenindustile method and it can be used both tototechnical as well as slebdrucktechnleche Maeklarungsvarfahren followed by etching. In addition, structuring by laser beams is also provided.

As a third embodiment, light elements of long-lasting luminescent substances are described in the form of strips: Cost-effective, zinc sulphide, long-luminescent pigments are used. These are embedded in a polymeric matrix and applied with conventional coating technologies. The use in the form of a seibstkiebenden strip has the disadvantage of a relatively low persistence and low resistance to UV radiation and water vapor. '.1 10 15 20 25 12 • · »··· * * • · * • · · · · · • ·» ·

In the present case, there is no ei ne Wesserdempfbelastung, nor a high UV exposure at de r arrangement in the interior of a Isollerglaselementes. By virtue of deer glass panes in the form of float gies or cast glass, at least the IIV-B radiation is greatly reduced and optionally an additional B < »Stratification also reduces UV-A radiation

However, aluminas and silicates doped in the present invention and / or a mise are particularly rare earth-type and the like are inorganic pigments, zinc sulfides

Phosphors and also strontium-aluminate pigments. Conventional pigments based on strontium aluminas are available in very fine-grained sizes of a few micrometers, typically 10 micrometers, up to coarse-grained pigments of typically 50 micrometer dimensions. They have long-lit fluorescents from above 20 hours to within 50 hours and emit in a typical wavelength range of about 400 nm to 540 nm. Typically, the yellow field at about 520 nm is best perceived by the human eye. Not only the annealing can be used in the UV range. It is already possible to use conventional artificial lighting, for example on the basis of fluorescent tubes, to illuminate other lamps. Usually, the excitation in the range 200 to 450 nm will be carried out with good efficiency and a typical maximum at 380 nm will be achieved. Usually, the duration of the stay for escape route markings is measured according to DIN 67510 and wide standards. The dark adapted eye still takes the approximate values of about 0.01 mod / rrP

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• * ♦ »» φ · ··· · · · · ♦ · · »• · · ·» 13 In dar DIN 87510 is; 0.3 mod / m * is recorded as the value which is metrologically used for the persistence of a system for comparison purposes and must be above 5.7 hours. Furthermore, long aftergrowth systems according to DIN 67510 must have a luminance of more than 2.8 mcd / mk after 60 minutes in a dark environment.

In addition to the commercially available strontium aluminates, silicates 1 based on rare earth-doped long replica pigments are of interest due to their high temperature range up to the range 800 to 800 ° C., but such pigments then have shorter persistence times.

All information and features disclosed in the documents, including the abstract, in particular the three-dimensional design shown in the drawings, are claimed to be essential to the invention insofar as they are novel individually or in combination with respect to the prior art.

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The invention will now be described in detail with reference to several embodiments. Here are the advantages of the drawings and their description and features. 25 shows;

1 shows a schematic representation of an arrangement according to the invention in a sectional view, wherein an EL strip (11, 23) is arranged on the left and right on a standard profile frame (4),

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2 shows a schematic representation of an arrangement according to the invention in a sectional view, in which embodiment an EL strip (11 × 23) is arranged on the left and right of a profile frame (4), which is provided with a reflector (14),

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Figure 3 is a schematic representation of an arrangement according to the invention in a sectional view, with an LED strip (11,24) on the left and right is arranged on a standard Profilirahmen (4), Figure 10 is a schematic representation of an inventive arrangement in a sectional view In this embodiment, on the left and right, an LED strip (11, 24) is arranged on a profile frame (4), which is provided with a reflector (14). 15 Figure 5; a schematic representation of an arrangement according to the invention in a sectional view, in which case only the frame (4) with a EL-Strelfen (11,23) is dargestelit,

FIG. 6: a schematic representation of a typical EL strip 20 (23),

Figure 7; a schematic representation of an inventive arrangement in a sectional view, in which case only the frame (4) with an LED strip (11,24) is shown,

FIG. 8 shows a schematic representation of a typical LED strelf (24), 26

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Figure 9 is a schematic representation of a Erflndungsgemaßen arrangement in a sectional view, in which case only the frame (4) with a long-luminescent layer (29) is shown, 5 Figure 10 is a schematic representation of a Erflndungsgemtften arrangement in a sectional view, in which case only the frame (4) is shown with a long-lasting luminescent layer (29) with a mounting means (13), Figure 11 is a schematic representation of a device according to the invention

Arrangement ln sectional view, only the frame (4) with an LED strip (11, 24) and a plastic profile (33) being shown here, FIG. 12: a schematic representation of a frame profile (4) in a sectional view with an undercut (32)

FIG. 13: a schematic representation of a frame profile (4) in a sectioned view with an undercut (32) and a layer (3) with long luminescence (FIG. 3),

FIG. 14: a schematic representation of a frame profile (4) in sectional view with an undercut on the outside (32), FIG. 25: FIG. 15: a schematic representation of a frame profile (4) in a sectional view with an undercut obliquely outboard (32), * · • · • 9

I 16

16 shows a schematic representation of a frame profile 4 in a sectional view with an undercut 32 in the profile cavity and with a reflector 14, FIG. 17 shows a schematic representation of an LED strip 24 with an LED component radial connections (37),

11 shows a schematic representation of an LED strip (24) with an LED chip inaccurate (49) on a lead frame (24, 38), 10

FIG. 19 shows a schematic representation of an LED strip (24) with an unheated LED chip (49) on a printed circuit board (40). In the on-board (COB) technique, FIG. 20: a schematic representation of a green chip according to the invention Arrangement in a sectional view, wherein here the frame (4) with an LED strip (11,24) and a glass element (41) is shown,

FIG. 21 shows a schematic illustration of a mounting arrangement 20 in a sectional view, the frame (4) being shown here with an EL strip (11, 23) and a laminated safety glass (42),

FIG. 22 shows a schematic representation of a device according to the invention in a sectional view, the frame (4) being shown here with an LED strip (11, 24) and a glass element (41) having a groove (43), 17 17. «··· ·· ·································································

FIG. 23 shows a schematic representation of an arrangement according to the invention, in a sectional view, the frame (4) being shown here with an EL strip (11, 23) and a glass element (41, 42) and a frame element being asymmetrically elongated, and FIG such a reflection (16) of the light emission (15) is given,

FIG. 24 shows a schematic representation of a device according to the invention in a sectional view, the frame (4) being shown here with an LED strip (11.24) and a glass element (41, 42), and FIG. 10 shows the arrangement of the LED strelfens (11, 24) ) takes place laterally to the glass,

FIG. 25: a schematic representation of an arrangement according to the invention in a sectional view, the frame (4) being shown here with an LED strip (11, 24) and a glare element (41, 42), and FIG. 15 the arrangement of the LED strip (11 , 24) takes place laterally away from the glass,

FIG. 25 shows a schematic representation of a device according to the invention in a sectional view, the entire glass element (1) being fastened in an outer glass element frame (45) and 20 light elements (11, 23, 24, 29) being shown in different positions,

FIG. 27 shows a schematic representation of a connection arrangement in top view and with a circumferential light element 11;

FIG. 28: a schematic representation of an arrangement according to the invention in plan view and with light elements (47, 48), i 25 ί! 16!

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Figure 29 is a schematic representation of an arrangement according to the invention in plan view and a glass element (41, 42) with glass frits (44) and a frame element (4, 45, 45). t i

FIG. 30 shows an arrangement with a glare element (41, 42)

Glass cutting elements (44) and a frame element (4.5, 45) In plan view with a frame (4, 45, 45) on the left and right glass edges (41, 42)

Figure 31 shows an arrangement with a glass element (1) with Llchtelementen i 10 (11,23,24,29) in Innenrauh (18). One of the coatings (6, 7, 9, 9) can be mirrored or carried out with a sun protection effect, and such a light element (11, 23, 24, 29) can be arranged in a hidden manner, thus enabling special light effects

In Figure 1, an arrangement is shown in a sectional view, with left and right an EL strip (11,23) is attached to a standard profile frame (4). 20 This arrangement is a typical leolierglaaaufbag, two Gletelemente (2, 3) made of float glass or Gießgtss or laminated safety glass by means of a spacer (4) in the form of a profile frame and further a seal (5) made of, for example Polyvlnylbutiral (PVB), silicone, Polyurethane (PU), polyethersulfones (PES), polysulfones (PSU) and the like 25 joined together

In this case, a hermetically sealed interior (18) is formed, which is usually affected by an Edejgas, the gas pressure is adjusted according to the barometric air pressure at the place and at the time 30 production. Thus, at the time of production, it implies an i • e • e · e · e · e • e • • • ♦ ♦ ♦ <

Balance between the pressure in the glazed dunnage and the outside barometric pressure in the product environment.

The interior of the frame profile (4) is filled with tearing means (10) and the frame profile (4) is provided to the interior (1Θ) with perforations (17). As a result, the interior (18) is kept free of water vapor, which is quite essential for the life of conventional EL strips (11, 23) in use in such long-life glass elements (1). ; io 15 i

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The electrical connection (12) of the Llchtelamantes (11,23) is ausgefQhrt such that the corresponding lines (23) through the Rahmenprofll (4) are guided and sealed by the seal (5). In order to achieve a correspondingly long-lasting sealing, lines (23) must be used, which do not allow gas exchange with the interior space (18), such as, for example, painted-up copper wires and the like. ! For the operation of EL-Strelfen (23) so-called EL Invertar 20 or converter are required. Usually, a DC low voltage is converted into an AC of several hundred to 200 V and above and frequencies of 50 Hz to 2,000 Hz and above to outside the listening range. Depending on the design, such electronic components can be arranged in the interior space (18) or in the interior of the frame profile 25 (4) or outside. i j

The Lichtemleslon (15) takes place from the Oberflfiche of EL-Strelfen (11,23). By means of a corresponding bi-layering (6, 7, 8, 9) of the glasses (1, 2), it is possible both to produce discontinuity effects of the emulsion radiation (15). as 30 mirrored effects are also bejwlrkt. Depending on the choice of the splitter layer (6,7, Θ. 9), an EL coating can also be fixed invisibly directly in the interior (18) on one of the surfaces of the glasses (1,2).

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The attachment of the EL-3treifen (11.23) on the inside of the frame profile (4) can be done with a fastening means (13). For this purpose, self-adhesive systems or cold adhesive systems or 5 hot melt adhesive systems and similar fastening means can be used. The EL strip can also be arranged around the circumference or in pieces.

FIG. 2 shows an arrangement in a sectional view. wherein io left and right an EL strip (11.23) is attached to a profile frame (4) with a angefbrmten reflector (14). The arrangement of the reflector elements (14) allows the light emission (15) of the EL strips (11, 23) to be guided in a desired direction by reflected light (16). All other details apply analogously to FIG. 1. 15

FIG. 3 shows a schematic representation of an arrangement in a sectioned view, with left and right sin LED strips (11, 24) being arranged on a standard profile frame (4). The light emission (15) of the LED (25) can be deflected or reflected (16, 16 ') on the one hand by the Qrenechelchten 20 of the glasses (1,2) and / or by the coatings (6,7,8,9).

Usually, when using LED strips (24), a plurality of LED components (25) are routed in series, whereby the power supply 25 can be brought to typically 12 or 24 or 48 volts and thereby the required operating current can be reduced. The supply of energy is very easy by means of electrical Anschlußusalaitungen (12), which are guided by the Rahmenprofll (4) and sealed by means of the seal (5). Pie terminals (12) must also be protected against gas diffusion, which is well achieved, for example, with enamel-coated copper wires

I 21 21 ♦♦ ···· • Φ * • ♦ · · · · · «

The at least one LED Strelfen Kenn as described in Figure 1, by a plurality of attachment methods Ober a fastening means (13) on the inside of the profile frame (4) are attached. For high power LED-Strelfen (24), the heat dissipation of the frame profiles (4) S can be used. In particular, an aluminum is as

Frame material suitable. The contacting of the LED-Strelfen can be done in such cases with good heat-conducting fastening means (13). All further details apply analogously to FIG. 1. FIG. 4 shows a schematic representation of an arrangement in a sectional view, wherein in this embodiment left and right an LED line (11, 24) is arranged on a profile frame (4) Is provided with a reflector (14). Thereby, emitted light (1 $) can be reflected (16) in a desired direction. All fifteen further details were analogous to those of FIG. 1 and FIG. 3. FIG. 5 shows a schematic representation of an arrangement in a sectioned view, whereby only the frame (4) on the inside is designed with an EL element (11, 23). The attachment 20 of the EL strips (23) by means of Befestigungslgungsmlttel (13) can be carried out as described in Figure 1 by a variety of methods.

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A commercial EL strip (23) can be produced in very long lengths of typically 90 or 100 meters and above. In this case, aluminum foils are usually separated by various processes and thereby EL-splite electrodes (19) are produced, which hardly cause a voltage drop by their good conductivity over very long distances and thus enable the operation of such EL strips (23) over very long lengths.

I 22 22 ··· ···· ··· # ·· • · et e · · · · · · · e v

On the EL splitter electrodes (a dielectric layer g 9) is an insulating layer or "and give it a largely transparent polymer matrix with zinkeulfldischen electroluminophores (20) of typically some 15 to £) micrometer-sized pigments and about a transparent Deckelek oxidic and / or metal nlt ode (21). Typically, metal-chemically microencapsulated electroluminophors © (20) are used and thus ki nn the so-called half-life can be increased to some 2,000 hours i

The lamination of the EL strips (23) plays a role in this, since they are subject to severe degradation in spite of the microencapsulation of the ion lektroluminophor (20) in operation at elevated temperature and the Elnfluf of moisture. The aluminum spliter electrodes form an excellent water vapor barrier. Dia tra jisparente or largely transparent cover electrode (21) preferably indium Tin-Oxlde (ITO) or non-ITO or from elektri eh loitftthlgen and transparent polymers, offers at elevated temperature! However, in the present invention, these life-restricting properties do not matter because in the interior space (18), in any case, the water vapor portion is extremely small.

FIG. 6 shows a top view of a typical EL strelfens (23). The EL emission (15) is only caused by the reflection of the split electrode (19). The electrical connections of the reporting split electrodes (19) are usually carried out by Crimpar lehlüsse (22). IQ / 05 'Oi HT 1fl.K4 rcü / mi xm inici 23 • ····································································

• · · > I · V ·······················

In Figure 7, by analogy, the arrangement ln is cut. In contrast to the use of high heat transfer, the fixing means of Figure 5 is a schematic representation of a view with an LED bar (24) shown as an EL strip (23) For gs-LED strips (24), pay attention to a good bnprofile (4) and select [13] accordingly. : u: l i!

In Figure 8, a typical LED Strelfen (24) is shown in plan view. Such a LED strip is the company Osram Opto Semiconductors 10 GmbH, D-93049 Regensburg! Germany with the type designation LINEARIight flex OS-LM11A | u refer. Such a LED-Strelfen example, with a total length of 8.4 m and a basic size of 10 LED'S (25) as the smallest LED unit (28) nit 140 mm in length with a height less than 3 mm and a strip width vn 10 mm in the form of a flexible Substrate (26) 15 delivered. Such 140 mm units can easily be separated from the roll by means of scissors. D 8 LED grid spacing (27) is 14 mm in this version. The Rüd riding this LED strip is self-adhesive. The power supply is done by 24 Volt DC (12). Nominally, the smallest unit to be operated of 10 LED's with 140 mm long length per emission color i needs between 40 and 50 mA nominally to produce a luminous intensity of 95 mcd (blue to 305 mcd (white) and 730 mcd (yellow) In such unites of 10 LED's, 0.98 to 1.2 Wt and 6.9 to 8.6 W, respectively, are available per meter, and the wattage of these LED components is 120 * .25

FIG. 9 shows a schematic representation of an arrangement in a sectional view. jt, where only the frame (4) is shown with a long-lasting light-emitting layer (2 I). Since the surface is very well reflected by the use of aluminum as the material for C is Rahmanprofll (4), the inside of the frame profile (4) mR of a brightly glowing layer (29) of a well ιο / ηκ 1 η λ ντ 1 fi · R Λ rcc / cu md

II. ··. ······· ·· ··· · * · * · ··, J! ; ·································································································································· An adhesive and transparent polymer matrix (31) mtt nachleuhtenden Pigmentei (30) are coated. The coating can be done by brushing, Rak In, dipping. Spraying, screen printing and the like Versetzungsr iethoden done. In most of these methods, the Rahn inductions (17) remain free. However, a subsequent production of these frame openings (17) can also take place. When using koster, listen to cheap, zinc sulphide-rich, luminescent phosi (30) Paying attention to the freedom of the welter, as this will ensure that the duration of the nasal life is maintained over a much longer period of time. Dii drying of the polymer matrix (31) with the phosphorus pigments (30) k inn, depending on the design of the polymer matrix (31) thermally or radiatively. FIG. 10 shows a schematic representation of an arrangement in a sectional view of a post-emergence layer (5 15 20, only frame (4) with a long I) with a bonding center (13) being shown. Self-tapping long-peeking films (29) with back-gluing (13) sln < commercially available. In the present

Arrangement must be secured to the fastening means (13) in the interior (18) so that the polymer matrix (31) imd a Wasserdsmpfeinbrnnung cause in the, or no excessive outgassing. Feiler must be taken to ensure that the frame breakthroughs are not "covered. In FIG. 11, a schematic representation of an arrangement is shown in a sectioned view, wherein only Rahman (4) with an LED strip (11, 24) and a plastic profile (33) is shown. The plastic profile (33) has the function of holding and positioning the LED strip (24). In this case, wen for fastening the Kunitstoffproflls (33) 30 snap hook (24) darges rode, which are introduced into openings (17). Instead of Schnapphaker (34) can a variety of others

1fl / 0S '04 MT 1R? R4 fSR / RM MR 771 RI 25 10 15

Find connectors on use. It is aperture (35) is only exemplified and use of the LED (an asymmetrical lid partially mirrored, also reflects the opening (35) for Lij • a • it eee # • § ·· ee • ee • e ·· • aee • eaeeae • ee · ea ·· eee ·· ae ea seee e eee e eee ice of squeeze pin and the like hehe opening for the LED (35) shown These shown .It may depending on the training 5) the opening (35) with a reflector or guide element or be provided with an element. However, htlelteffekte can be availed.

In a further development, this «attachment hook (33) on a long-luminescent P g langnaehleuchtenden Plgm <

In the embodiment, the plastic profile mH can be made transparent and ment (30) forms a polymer matrix with it (36).

FIG. 12 shows a schematic view of a schematic representation of a frame profile (4) in the undercut (32) of FIG

Undercut (32) Is only given ipielhaft and is to show that yes after Oaführungsform the ichtelementee (11) a simple

Filling possibility ohi e additional cost is possible and also during installation no special need for auxiliary tools. 20

FIG. 13 shows a schematic representation of a frame profile (4) in a sectional view with an undercut (32) and a long-line illuminating loop (3). In this embodiment, the back section (32) is used to receive a light element (11). so experienced. It is exemplarily shown that a long-lasting luminescent layer (29) in the form of long-lasting pigments (30) in a polymer matrix (31) is likewise incorporated in one of the profile frames Can be integrated and additional functions can take n. 25

I •••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••

In Figure 14 is a shear ΐ cut view with elt shown. Such an Aj can be used since there is no 26th representation of a frame profile (4) in | < in the outer undercut (32) rführung can very well for shop window ^ glare of the viewer is possible. FIG. 15 shows a schematic illustration of a frame profile (4) in a sectional view in FIG. 1 with an obliquely outer undercut (32). Similar to Fig. 14, such an arrangement can be used very well for the illumination behind the glass element (1). FIG. 16 shows a diagrammatic representation of a frame profile (4) in a cutaway view with an undercut (32) in the profile cavity and FIG. The reflector (14) can be in the i and surface designs with a reflector (14) on the desired geometric! 15 be designed and da ltlt desired radiation characteristics can be adjusted. The öffr ig (35) for the LED (25) can exactly on the

Size of the LED (25) can be stifled, but it can also be done over the entire profile (4) (b) (24) simply and the qe is possible. i, allowing the mounting of the LED strip position of a complete frame (4)

In Figure 17 is a schei spawning representation of an LED strip (24) 25 with an LED component with r | LED elements (37) are available in. In this case, Kul housings made of plastic odpi the Lichtemiseion (15) are power range in very effective lighting effects in profile i Halen terminals (37) shown. Such ler variety of different designs itetoff-Llnsenkörper or lenses made of glass and metal can be used. The angles of emission> as well as the colors and the areas selectable and aa can be achieved very much (4). As substrates 30 flexible Lelterplatteni! and rigid and rigid-flexible printed circuit boards 27 VI ·· ♦ · ♦ · or semi-flexl {each circuit board in one-sided, double-sided and multilayer design can be used. p

In FIG. 10, a schematic representation of an LED strip (24) with an LED chip (not shown) Jist (49) on a lead frame (24, 38) is shown. This leadfran technology is usually the 10th

Production of individual LEDs used. Basically, ei 3 (25) in radial AnschlußausfOhrung ien such lead frames for the production of very kosteruünstigen LED Stralfen. However, the principle of parallel and side switching of LED components must be considered. 15 20

The very cost-effective parallel connection very high currents in the Vfl components. Bel der serii be used to make a The LED chip (49) is mounted at the newly formed end of a conductive and that contacts the bonding wire (39) on one. In addition to this B (contacting methods for He components (25) possible. Causes small voltages and jwendung a variety of LED ijjischschaltung must avoid damagingouble overloading of each LED.; L fcjt hugely directly on a as a reflector frame part electrical and thermal good idj The end of the photodiode (49) is now an additional 1-position of very powerful LED-25 by means of s connection element of the lead frame iftd technology. In FIG. 19, one will see a tremendous LED on-board (COB) technique This method is flexible in that the device (49) is chip-printed on the display of an LED Strelf (24) chip (49) on a printed circuit board (40) .This is a very cost effective device LED strip (40) In 1 noble contact of the unheated LED b jirat (40) and the bonding wire contacting (39)

I 30 28 II • ♦ ··· * ♦ · of the other pole Again, a number of other technologies are possible and feasible.

FIG. 20 shows a schematic view of an arrangement in a sectional view, wherein the tap is shown in FIG. (4) with an LED strip (11, 24) and a glass element (41). Glass elements (41) have thicknesses of about 3 mm when using tyon float glass, about 16 mm when using composite glass and above, and can be formed from several gauges in Slchertaitsglastschnik (42). In this embodiment, the emitted light is soldered over at least one side edge In of the glass element (41). In such glazing (41) can machine by CNC-controlled Fri largely arbitrary 15th

Depending on the design of the cutting elements (44), ie the shape, the depth, the surface of the recess and the like, very different light effects may be produced -Strelfen (11,24) In who

Areas are chosen arbitrarily. In Fig. 21, an arrangement in a sectional view is schematically shown, wherein the frame (4) is shown with an EL Strelfen (11, 23) and a composite safety casting (42). Simple thick glasses (41) are also related. To increase the life of the one EL Strelfan (23) - which may have a plurality - the area in which the EL-i grasp (23) is positioned must be sealed so that no leakage occurs rapidly -Strelfens (23) can cause. This is achieved duttjh training of the frame profile (4) filled with Trocknungsmittiilj (IO) and the seal (5). In Figure 22, an anordaku 30 is shown, with the frame | a glass element (41) with < fl * mg in sectioned view is shown schematically with an LED * Strelfen (11,24) and ler groove (43) IsL In principle, 1 n / nc f λλ is 1 OI C ron / nu in kh «· ι 29 10 15 20 25 Γ! • · · · · · «Μ ·« · · · · # * · > Here, too, a sleightiness element (42) based on one or two or more disks can be used. The groove (43) is made depending on the configuration of the LED (25) and can be selectively or as Lflngsnut with a corresponding li phtleiteffekt be made. In Fig. 23, an arrangement is shown. The frame (4) glass element (41, 42) shown asymmetrically extended to the light source (15) is shown in sectioned view schematically I St with an EL strip (11, 23) and a j, and thereby a frame element is guided, with a refiection (16) the nlit,

In Figure 24, an arrangement is shown schematically in sectioned view, where the frame (4) is shown with an LED strelft (11, 24) and a molding element (41, 42) 1, respectively. The arrangement of the LED-Stralfens (11.24) takes place laterally to i ijas. In this way, light emmissions can be carried out very well directed. In analogy to FIG. 22, a groove (43) In > i the glass element is frozen, so that the LED building element (25) is received therein. The groove jf3) can be made punctiform or longitudinal. It is also possible to use multi-disc Dickgliser (41, 42).

In FIG. 25, an arrangement is shown schematically in a sectional view, in which case the figure (4) is shown with an LED line (11, 24) and a glass element (41, 42); The arrangement of the LED strip (11.24) takes place laterally away v i in the glass and can be noeh by the special design of the Prcliirahmans (4) with reflectors (14) gestured in a desired direction ijrt. In this arrangement, the glass element (41,42) is not moistened. However, it is easily conceivable that this arrangement can be combined with a previous arrangement.

I 30 ·· »· · · · · ···· · · · · ·

Mf · t ΜΦ · · II · ·

In Figure 26 is a Anon development In a sectional view schematically dargastellt. wherein the entire glass element (1) is located in an outer glass element frame (45) and light elements (11, 23, 24, 29) are in different positions. The electrical connections (12) are omitted when using p long-luminescent elements (29). The Uchtelement (1) can be folded nit a Uchteffekt according to one of the aforementioned embodiments. The glass element frame (45) may be made of wood, aluminum, plastic, stainless steel, coated iron profiles and the like materials. 15

In FIG. 27, an arrangement is shown schematically in a top view and with a circumferential light source (11, 46). Basically, such | ge longitudinal light elements (11), as shown in this illustration, h Iumlaufend (46) are simply and inexpensively ausgelldet. The single electrical connections (12) are shown only by way of example with two lines. Depending on the type of Llchteiementes (11) and multiple connections can be used 20 and it can then beispie engesteuert. For example, multicolored LED (25) elements 1 I1in such different color coordinates can be selected electronically and / or controlled by sensors. It is also possible for me I jere light elements (11) or more I segments of a LichtelemerSs (11) offset in time or 1 J be controlled by a corresponding El | i | ktroni6Che or manual control.

In Fig. 28, an arrangement is schematically shown in plan view and with piecewise arranged elements || (47l 48). In such an embodiment, the coats for the upper surface elements (11) were saved. It may, however, require the graphic design of such an arrangement. The electrical connections (12) are shown separately in mm / m · m · t 30 · 31 · 15 · 15 · 25 in / ns · λι ut Ιβ.ΡΙ r nn mw. By the way, frame profile (4) becomes > llji

In Figure 29, an Anorc GlesfrAselementen (44) is shown un schematically at the lower edge of the glass (

Such connections are usually brought together in the circuit element (12) with a glass element (41,42) with m frame element (4,5,45) in plan view el, the frame (4,5,45) only, 42) is shown by way of example. dj sine

In Fig. 30, an anorc j glass milling elements (44) are schematically illustrated. Dali of the left and right glass ung with a glass element (41.42) with fine frame element (4,5,45) in plan view I ei example, the frame (4,5,45) to ante (41,42) is shown.

FIG. 31 shows an anorcic light element (11, 23, 24, iung with a glass element (1) with |: 9), wherein the light elements (11, 23, 24, 29) are mounted in the interior (11). In a special embodiment, coatings (6, 7, 8, 9) may now be mirrored or applied with sun (protective effect) and hidden (11, 23, 24, 29) hidden, providing nightlighting effects such special is also combinable with d < ji already described embodiments.

Furthermore, such an An can be realized. Reflective graphic background of the light element J can be formed in a colored translucent or, alternatively, the glass interior 8.9).

Even in multithreaded embodiments, in this particular embodiment, translucent designs can be demonstrated on n (1,2) and / or the coatings (6,7, but opaque or derivative ones can be made, and {11,23,24,29) accordingly 1 wjsiti iuL be »

Ifl / nC ♦ ΛΛ UT 1 O. P rrm / nu * rr »30 32 10

Items 1 1 '1 " Γ * 2 3 4 5

Glass element with glass frame glass element with glass element glass element with simple light frame glass element element i ilt light frame and outer glass element frame glass exterior (Floatglai and the like) glass interior (float glass i.dgln,) frame (spacer profile / profile)

Seal (Polyvinylbul Polyethersulfone (PE

6 Coating Glass ai 7 Coating Glass au 8 Coating Glass in 15 9 Coating Glass Inr 10 Desiccant (Mol 11 Light element 12 Electrical connection 13 Fastener 20 14 Reflector 15 Uchemia 16 Reflected Ucht 17 Frame break in 18 Interior (high molar 25 19 EL splitter electrode (RQ (PVB), silicone, polyurethane (PU),), polysulfone (PSU) and the like ) n-outside

Substance en lares noble gas, e.g. Argon, krypton, etc,) electrode) tO / AR '04 uT Ifi · C4 ret? / w \ u u. •••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••• 30 15 31 32 33 34 35 20 36 37 38 39 40 25 41

Electroluminophors Transparent ceilings (Indlum-Tln-Oxlde ITQ, non-ITO, electrically insulated and transparent polymers and the like; floating or connected to a {splice electrode) Crimp contacts EL luminous strip LED strip LED LED substrate (FPC) Flexible Prlnted Circuit , Rigid, Semiflex, Aluminum PCB ... F rinted Circuit Board, etc.) LED grid miniature LED unit Long-afterglow

layer

Long-lasting lucent pigment

Transparent polyme undercut for affixing a light element (11) Plastic profile with Bf fastening element Snap hook Opening for LED

Polymer matrix with lan jjnechleuchtenden

Pigments LED with radial contact lenses

Lead Frame Bond Turns

I

Chlp-on-Boerd (COB) j glass element (Floatgli i, Verbundaicherheftaglaa, Gullglas, Verbund-

Security gigs, thick

Glare elements 16 mm, etc.) in / ap «ut 34 ··· ·· ···· Μ« «·· ····· ·« «* • · * ··· · · ···· • · · · ····· · 42 43 44 45 46 47 48 49

Composite SichBrhehsdas

Recess in the glass dimention (groove, milling groove, etc.)

Glass Milling Elements Outer glass element emulate the light element circumscribing the light element at the top

I

Light element piece by piece below LED chip unhoused 10 19/05 '04 HI 18:54 TSE / EM NR 77151

Claims (25)

1. Glass element (1) of a 5 light element (11) on the inneji characterized in that the strip (23) is formed is 10 2. Glass element (1) of a light element (11) on the Inn ····················································································· Profile frame (4). characterized light element (11) of at least one EL · solisrglasaufbaues with at least one ic iselte the profile frame (4), characterized in that dsf light element (11) from at least one LED · strip (24) is formed, 16 3. Glass element (1) of a glass roller assembly with at least one light element (11) on the Inn «iseite of the profile frame (4), characterized in that da light element (11) is formed from at least one. luminescent layer (29 4. Glass element (1) according to claim 1 to 4, characterized in that daee the light element (11) from a combination of two or three of the 24,29) is formed. said light elements (23 5. glass element (1) after that at least one Lichteleijni 25 is arranged and the Inns is. Claims 1 to 5, characterized in that ent (11,23,24,29) in the interior space (18) nhum (18) are kept free of Waseerdampfbelastung 36 36 • · • · · · · · · · · 6. glass element (1) according to claim 1 to 5, characterized in that the at least one Lies slsment (11,23,24,29) by the arrangement and / or design of the projectile frame (4) is arranged such that the Lichtemisslon ( 15) directly undipder via reflectors (14) and / or coatings (6,7,8,9) whose reflected light (16,16 ') are brought into a desired direction ka in, takes place. 7. glass element (1) according to t jmspruch 1 to 6, characterized in that data at least one Lieh element (11,23,24,29) by Kaltklebetechnlk, i 10 Helßschmelzklebetechnlk, Cr mptechnlk, snap technique. Fqgetechnik is fixed by screwing and the like mounting technology on the profile frame (4). 8. glass element (1) according to claim 1 to 7, characterized in that the lighting element <11) a (jf base of an LED strip (24) by means of a Kunststoffprofils with a Bs (estlgungselement (33) and an opening for the LED (35) on the Rahmenprc fil (4) by means of snap, crimping, pushing and the like techniques posltic ilert and attached Ist 9. Glass element (1) according to / inspruch 8, characterized in that the plastic profile is formed with a fastening element (33) with long-luminescent pigments (3 | D) in the form of a polymer matrix (31) 10. glass element (1) according to n that the frame profile (4) m of a Uchtelementas (11,23, say 1 to 9, characterized, [an undercut (32) for the attachment 24,29) is formed (see Flg. 12). 19/05 '04 MT 1Λ · K4 rsw / t? M wu 77ΐκι II 10 15 20 25 37 ·· ··· # ·· ··· ♦ · · · · · eee «·« · · · · · » 11. Glaeelement (1) according to claim 1 to 10, characterized in that the frame profile (4) with a laterally arranged undercut (32) for the attachment of a lid member (11,23,24,29) is formed and on the inner side of the Proffrrahnr ans (4) a long-luminescent layer (29) aulweist (see Fig. 13). 12. Glaeelement (1) according to claim 1 to 11, characterized in that the frame profile (4) is formed with a laterally arranged half-section (32) for the attachment of a Lid] eiementes (11,23,24,29), wherein the Light emission of Lichteid Mentes (11,23,24,29) is directed outwards or at an angle ausgeldsblldet (Flg. 14 and 15). 13. glass element (1) according to intpruch 1 to 12, characterized in that the Rshmenprofll (4) π attachment of an LED light t an Innenllsgsndsn undercut (32) for the Mentes (24) is formed, wherein the light emission of the LED (25 ) is influenced by a reflector (14) (see Fig. 16). 14. Glaeelement (1) according to /inspruch 1 to 13, characterized in that the LED strip (24) or SMT (25) ui and this photodiode Ko ultrasound technology, Lasertechi fitiele radial (37) and / or SMD / or Unhindered (49) LED elements formed iponentan using soldering, welding, and bonding technology on flexible and samlflexiblo and rigid printed circuit board substrates and / or Laad frames are mounted and Depending on the technology parallel odev zusammengescheltet in series at DC voltage of some 1 5 volts to 46 volts operate. 15. Glass element (1) according to P hspruch 1 to 14, characterized daas that at least one Lief delivery (11) is controlled by an electronic control 30 and so zö Itllch and / or color and / or intsnsitätsmfißlfl 19/05 '04 MI 18:54 fSE / EM NO. 10 16. Glass element (1 ') with connected profile (4) to at least one at least one piece or at least one or more Kenten a glass element (1') with at least one longitudinal light element (11), characterized in that the light element (11) attached to a profile frame (4)! t and the light element (11) consists of an EL strip (23) and / or eir in the LED strip (24) and / or a long * luminescent element (2S consists. 17, glass element (11) according to - claim 16, characterized in that the glass element (41,42) gralisch designed glass cutting elements (44) aultaelst and these by means of mechanical »milling devices and / or by means of high pulsed 15 ablative laser systems mountains are sharing and optionally with color glazing or 18th glass element (V) according to in that the Rahmanprofü (4) in a what a seal (5) abgedlchtel frame profile (4) attached isluzenter colors are additionally designed. 20:25 is therefore 16 and 17, thereby Jocholement (11,23,24,29) is arranged with the rdampMraien surroundings and is with and in particular on dar inside the st. 19. Glass element (1 ') with at least one longitudinal light element (11) on a glass element (41, 40), characterized in that the glass element (41, 42) delimits an elongated recess (43) or an oblong recess (43). Wkkun ngrsdes the irradiation of an LED (25) autelst and this Auseeprun (43) is arranged on one of the front sides and / or flat sides of the Glaeelementes (41 42) and is covered with the Rahmenprofll (4) i 30 39 ··· ·· ···· ·· Μ «· • * ·· ·« «« · · · ··! · · «« * # '• · · · · · · · · · 20. Glass element (Γ) with at least one longitudinal LED Strelfen (24) on a glass element (41,4 2), characterized in that the LED Strelfen (24) is mounted in accordance with the Profilirahmen in recesses (4) and with a good WänfneObergang to Rahmenprofll (4) are attached to this. 21. Glass element (1) characterized by zl characterized in that it comprises a lense (1, 2) and / or a longitudinal light element (11), that the light element (11) on the inside of a coating (6, 7, 8, 9) in the interior (18) of a Isollerglasaufbaue is mounted 15 22. Glass element (1) with zl according to claim 21, characterized EL strip (23) and / or at least one longitudinal light element (11), the light element is a LED strelfen (24) and / or a luminescent Elemeijt, (29) or a combination of the three mentioned Uehtelemenu | n (11) and is flat in the interior (18) is attached. Glass element (1) having a at least one longitudinal element (11) according to claim 21 and 22, characterized in that one of the coatings (6, 7, 8, 9) is mirrored or semi-mirrored or designed with a sun protection effect 24 Glaaelement (1) mR 2 at least one longitudinal Uchtelement (11) 25 according to claim 21 to 23, de lurch characterized in that multi-colored LED (25) - elements are temporally and / or offset angeetuert. 19/05 '04 HI 18:54 [SE / EM NR 7715] • • • • • • • • · · · · · · · · · · · · · · · · · · · · · · · ·) 26. A method for manufacturing claims 1 to 24, dadurel longitudinal light element is attached, which is prepared as Absta 5. 40 ng of a glass element (1) according to one of the marked, that at least one preferably inside on the frame rdshalter serves and in the form of a profile 26. A method for the production of a glass element (Γ) according to one of claims 1 to 25, dadurel characterized in that the laollarglaaaufbau is ausgeafOhrt with a preferably approximately iresserdampfffreien interior, which is filled with 10 Inartgaa, for example k Irgon or Krypton or the like Gasmlschungen Method for producing a glass element (1 ") according to claim 26, characterized in that it comprises a desiccant or a so-called molecular sieve. 11 given the cavity of the frame profile wild. i I I ·