DE10322561B4 - Insulating glass element with light frame - Google Patents

Abstract

Insulating glass element, the glass elements (2, 3) of which are held parallel to one another at a distance by means of spacers arranged on the edges and the interior of which is sealed by a sealing compound attached to the edges, with several EL- Strips or LED strips or photoluminescent layers of existing light elements (11, 23, 24, 25) are arranged, which are directed into the interior (18) between the glass elements (2, 3), characterized in that on the profile frame (4) a reflector (14) is arranged which directs the light (16) reflected by the light element (11, 23, 24, 25) obliquely towards the inside of the glass element (3).

Description

The invention relates to an insulating glass element with a light frame based on Iongitudinaler light elements in the form of LED strips.

Typically, in modern glassware, two or more evenly or non-uniformly spaced flat glass sheets, also referred to as float glass, having a thickness of a few millimeters to about 21 millimeters, typically of 4 millimeters thickness and 16 millimeters spacing are used. The embodiments may be designed according to the properties for the heat protection, the sun protection, 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 × 3.21 meters and from these the panes for typical multi-pane insulating glass structures are produced. By the edge bond hermetically sealed spaces are produced, which are usually filled by a noble gas. The gas pressure is adjusted according to the barometric air pressure at the place and at the time of production. Thus, at the time of production, there is a balance between the pressure in the glazing unit and the external barometric pressure in the production environment.

In addition to these double, triple or even multiple insulating glass structures made of simple float glass, such multi-pane insulating glass structures can also be formed from disks which have a coating on one or both sides and thus the reflection and / or transmission and / or optical design in desired wavelength ranges of the light. The individual slices can be carried out biased or through-dyed or formed from so-called safety glass.

Safety glass or safety insulating glass is glass originally developed for the automotive industry for vehicle glazing and today such sandwich-type safety glass elements are increasingly being used in building technology. Basically, a distinction is made here between toughened safety glass and laminated safety glass and, in principle, both types can be used in the present invention.

In the EP 0 821 820 B1 is a lighting device with a body of transparent material, for example made of acrylic glass, and one or more band-shaped light sources described. Tape-shaped light sources are band-shaped printed circuit boards, on which light-emitting diodes in SMD technology are applied in a dense, compact sequence. Further, band-shaped light sources of electroluminescent film, which continuously generates light over its length, are shown. However, there is no description of a longitudinal light element in a profile frame with a glass element.

With the publication DE 102 05 405 A1 a window element with a display for image reproduction and a glass element arranged in front of the display is disclosed, wherein a light element is arranged on an end face of the glass pane and the display.

This invention has the disadvantage that it is not apparent from the arrangement of such a light element within an evacuated insulating glass element.

With the publication EP 0 324 710 A1 discloses an insulating glass pane having an embedded at the side edge, translucent tube having a light element which irradiates light in the interior space between the two glass elements of the insulating glass to light guide elements.

This document has the disadvantage that it is not apparent from the arrangement of such a light element within an evacuated insulating glass element.

With the publication DE 101 46 604 A1 is disclosed a window member consisting of a frame member and two spaced-apart glass elements and a laterally arranged light element, wherein the light element is formed of an LED strip and is arranged on the front side of one of the two glass elements.

With the publication DE 20 35 454 C3 For example, a glass element of an insulating glass structure having a light element on the inside of a profile frame is disclosed, wherein the light element is formed of an EL element and may be formed as a strip shape.

With the publication DE 195 29 737 C1 discloses a window element for illuminating interiors, comprising two spaced-apart glass elements, which are arranged in a frame construction, wherein between the two glass elements, a further, curved glass element and a laterally arranged light element is arranged, which is designed as a long-lasting luminescent layer. The disadvantage is that an arrangement of such a light element within an evacuated insulating glass element not too recognize. Another disadvantage is that only two light elements are arranged, which have a low light output over the entire window area.

Based on this document, the object of the present invention is to develop a light-emitting element so that it can be produced more cost-effectively and used with better light output.

To solve the problem, the invention is characterized by the technical teaching of claim 1.

An essential feature of the invention is that a reflector is arranged on the profile frame, which directs the light reflected from the LED light elements obliquely against the inside of the glass element.

The invention accordingly relates to a glass element having a light frame with at least one longitudinal light element in the form of an LED strip.

A typical safety glass structure consists of two float glass or cast glass panes 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 polyvinyl 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 refractive indices greater than 1 and less than 2, typically in the range of 1.5 and / or in the combination of Glass panes in combination with transparent plastic panes.

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 self-adhesive tape or hot melt adhesive system or by snapping or screwing or crimping or insertion and the like attachment methods.

It must be taken into account the different coefficients of expansion of the frame and the various lighting elements in operation. Usual frames are extruded from aluminum or various aluminum alloys. In principle, however, plastics can also be used. In special versions, 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 dissipation property and the good water vapor barrier function are an advantage.

In accordance with the invention, insulating glass structures with a preferably approximately steam-free interior offer themselves which are filled with inert gas, for example argon or krypton or similar gas mixtures. This is a water vapor barrier for EL elements.

In addition, usually a desiccant, or a so-called molecular sieve, placed in the cavity of the frame profile and the frame profile is provided with openings to the interior, so that water vapor residues are bound in the interior of a Isolierglasaufbaues. The frame is also circumferentially sealed with the glass sheets with a polymeric composition based on polyvinyl butyral (PVB), silicone, polyurethane (PU), polyether sulfones (PES), polysulfones (PSU) and the like.

In a preferred embodiment of the invention, the use of an LED strip is described.

According to the invention, so-called LED strips are used as a light element in frames for glass elements. In principle, all types 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 metal housings, conventionally mounted or wired elements can also be used on printed circuit board substrates.

Furthermore, surface-mountable LEDs, so-called SMD (Surface Mount Device) or SMT (Surface Mount Technology) LED elements or electroluminescent semiconductor elements are used in direct mounting on wiring substrates, that is unexpanded LEDs for the so-called chip-on-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 stampings in strip form, in which case lens elements and holding elements are carried out here by means of in-mold injection molding.

Conventional SMT LED components typically have a luminous intensity of 5 to 20 mCd at 20 mA and about 2 volt DC. The light intensity is the luminous flux related to the solid angle and SMT LEDs with relatively large solid angles of typically 100 to 140 ° are used. So wise Such surface mount components have a component height of 2.1 mm to 0.8 mm and are already available in a special design with a height of 0.55 mm.

High-power LEDs with a beam angle of some 5 to 30 ° already provide light intensities in the range of 25,000 mCd and in impulse operation also beyond. In such light levels, the dissipation of heat loss and the type of contact already represents a significant problem. For the use of the usual long life of some 10,000 to 100,000 hours, this problem must be solved. In the present case, the frame profiles, which are preferably made of aluminum, are suitable for dissipating the heat. In such cases, the wiring substrates must be thermally well conductively mounted on the frame profile. It is also possible to manufacture the wiring substrates from corresponding aluminum circuit board material.

Moreover, for a number of applications, not only the usual red and green and yellow and blue signal colors are of interest, but white light is preferred. Such LEDs are usually operated in the blue area. Color-converting lens bodies produce a white emission. In this case, inorganic admixtures are used in the polymer matrix of the lens body and thus extremely long-term stable emission spectra are achieved without color shifts.

In addition, there is still the possibility of using so-called R-G-B LED's, that is LEDs with 4 electrical connection elements and the emission colors red-green-blue. Although in such LED elements, the electronic circuitry is more complex, but it can be generated electronically and readjusted all mixed colors. Depending on the design of the electronic control unit, different color effects can be generated in chronological order and optionally controlled by means of sensors.

LED strips are produced on double-sided, flexible printed circuit boards with surface mounted SMD LEDs and other components based on a roll-to-roll assembly and bonding process and in multiple uses. Usual roll lengths are 100 or 200 meters and above. Preferably, a plurality of LED elements are connected in series and can then be operated, for example, with a supply voltage of 12 or 24 volts DC of such a unit.

For example, an LED strip from Osram Opto Semiconductors with the type designation LINEARlight flex OS-LM11A is used. Such an LED strip is supplied with a total length of 8.4 m and a basic size of 10 LEDs with a length of 140 mm and a height of less than 3 mm and a strip width of 10 mm. The back of these LED strips 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 emission color between 40 and 50 mA needed. Nominally, a luminous intensity of 95 mcd (blue) to 305 mcd (white) and 730 mcd (yellow) is effected. The power consumption of the 10 LED's is 0.96 to 1.2 watts or 6.9 to 8.6 watts per meter. The beam angle of these LED components is 120 °.

The operation of, for example, 1 to 10 LED running meters can therefore be done very well by inexpensive and simple power supplies and it is to pay attention to any double insulation regulation.

The beam angle can be adapted to the respective application and asymmetrical emission characteristics can also be achieved with special lens designs and / or attachments. Furthermore, it may be advantageous to install a diffuser. This can be achieved in the present case in the interior of the insulating glass element very easily by transparent elements with good light-conducting and scattering surface.

As a substrate for such LED strips one-sided and double-sided flexible printed circuit boards based on, for example, polyamides (PI) and / or polyethylene terephthalate (PET) or poly-ethylene glycol terephthalate (short name PETP or PET) and / or polyethersulfone (PES) and / or polyetherimide (PEI) and / or polyetheretherketone (PEEK) and / or aramid and / or fibrous flexible films and the like. In this case, thin copper foils and / or aluminum foils are applied and patterned according to the wiring requirements.

This can be done by the usual in the printed circuit board industry process and it can be used both photo-technical as well as screen printing masking process followed by etching. In addition, the structuring by laser beams is provided.

All information and features disclosed in the documents, including the abstract, in particular the spatial 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.

The invention will now be described in more detail with reference to several embodiments. Here are from the drawings and their description further advantages and features.

Showing:

1 3 is a schematic representation of an arrangement according to the invention in a sectional view, wherein in this embodiment left and right an EL strip (FIG. 11 . 23 ) on a profile frame ( 4 ) arranged with a reflector ( 14 ),

2 : a schematic representation of an arrangement according to the invention in a sectional view, wherein in this embodiment left and right an LED strip ( 11 . 24 ) on a profile frame ( 4 ) arranged with a reflector ( 14 ),

3 : 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 )

In 1 an arrangement is shown in sectional view, with left and right an EL strip ( 11 . 23 ) on a standard profile frame ( 4 ) is attached.

This arrangement is a typical insulating glass construction. Two glass elements ( 2 . 3 ) made of float glass or cast glass or laminated safety glass are fixed by means of a spacer ( 4 ) in the form of a profile frame and further a seal ( 5 ) composed of, for example, polyvinylbutiral (PVB), silicone, polyurethane (PU), polyethersulfones (PES), polysulfones (PSU), and the like.

This forms a hermetically sealed interior ( 18 ), which is usually filled by a noble gas. The gas pressure is set according to the barometric air pressure at the place and at the time of production. Thus, at the time of production, there is a balance between the pressure in the glazing unit and the external barometric pressure in the production environment.

The interior of the frame profile ( 4 ) is dried with drying agent ( 10 ) and the frame profile ( 4 ) becomes the interior ( 18 ) with breakthroughs ( 17 ) Mistake. This will make the interior ( 18 ) kept free of water vapor, which for the life of conventional EL strips ( 11 . 23 ) in use in such long-life glass elements ( 1 ) is very essential.

The electrical connection ( 12 ) of the light element ( 11 . 23 ) is carried out in such a way that the corresponding lines ( 23 ) through the frame profile ( 4 ) and by means of the seal ( 5 ) are sealed. In order to achieve a correspondingly durable seal, lines ( 23 ), which do not exchange gas with the interior ( 18 ), such as lacquered copper wires and the like.

For the operation of EL strips ( 23 ) so-called EL inverter or converter are needed. Typically, a DC low voltage is converted to an AC of a few hundred to 200 volts and above and frequencies of 50 Hz to 2,000 Hz and above to outside the listening area. Such electronic components can, depending on the design in the interior ( 18 ) or in the interior of the frame profile ( 4 ) or outside.

The light emission ( 15 ) takes place from the surface of the EL strips ( 11 . 23 ). By an appropriate coating ( 6 . 7 . 8th . 9 ) of glasses ( 1 . 2 ), both light refraction effects of the emission radiation ( 15 ), as well as mirrored effects are effected. Depending on the choice of the mirror layer ( 6 . 7 . 8th . 9 ) an EL strip can also be invisible directly in the interior ( 18 ) on one of the surfaces of the glasses ( 1 . 2 ) are attached.

1

Referenz ursprüngl. Anmeldung Mai 2003, Seite 17 ff.

The attachment of the EL strips ( 11 . 23 ) on the inside of the frame profile ( 4 ) can with a fastener ( 13 ) respectively. For this purpose, self-adhesive systems or cold adhesive systems or hot melt adhesive systems and the like fastening means can be used. The EL strip can also be arranged around the circumference or in pieces. 1

1

Reference original Registration May 2003, page 17 ff.

In 1 an arrangement is shown in sectional view, with left and right an EL strip ( 11 . 23 ) on a profile frame ( 4 ) with an integrally formed reflector ( 14 ) is attached. Due to the arrangement of the reflector elements ( 14 ) the light emission ( 15 ) of the EL strip ( 11 . 23 ) in a desired direction by reflected light ( 16 ).

In 2 a schematic representation of an arrangement in a sectional view is shown, wherein in this embodiment left and right an LED strip ( 11 . 24 ) on a profile frame ( 4 ) arranged with a reflector ( 14 ) is provided. This allows emitted light ( 15 ) is reflected in a desired direction ( 16 ) become.

When using LED strips ( 24 ) usually several LED components ( 25 ) in series, whereby the power supply can be brought to typically 12 or 24 or 48 volts and thereby the required operating current can be reduced. The energy supply is very easy by means of electrical connection cables ( 12 ) through the frame profile ( 4 ) are guided and by means of the seal ( 5 ) are sealed. The connecting cables ( 12 ) must also be protected against gas diffusion, which is well met for example by enamel-insulated copper wires.

The at least one LED strip may be connected by a variety of attachment methods via a fastener ( 13 ) on the inside of the profile frame ( 4 ) are attached. For high-power LED strips, the heat dissipation of the frame profiles ( 4 ) be used. In particular, an aluminum is suitable as a frame material. The contacting of the LED strips can in such cases with good heat-conducting fastening means ( 13 ) respectively.

In a further development of this embodiment, the plastic profile with attachment hooks ( 33 ) are also made transparent and it forms a tang-luminescent pigment ( 30 ) a polymer matrix with photoluminescent pigments ( 36 ).

In 3 is 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 ). The reflector ( 14 ) can be designed in the desired geometric and surface configurations and thus desired radiation characteristics can be adjusted. The opening ( 35 ) for the LED ( 25 ) can be adjusted exactly to the size of the LED ( 25 ), but it can also be used over the entire length of the profile ( 4 ), so that the mounting of the LED strip ( 24 ) simply and after the production of a complete frame ( 4 ) is possible.

Furthermore, such an arrangement can also be realized in multiple glass designs. In a further specific embodiment, color-translucent or translucent designs can optionally be applied to the glass inner sides (FIG. 1 . 2 ) and / or the coatings ( 6 . 7 . 8th . 9 ). However, opaque or reflective graphic designs can also be made and the back side of the light elements ( 11 . 23 . 24 ) can be formed accordingly.

LIST OF REFERENCE NUMBERS

1

Glass element with light frame

1'

1''

1'''

2

Glass outside (float glass and the like)

3

Glass inside (float glass and the like)

4

Frame (spacer / profile)

5

Seal (polyvinylbutiral (PVB), silicone, polyurethane (PU), polyethersulfone (PES), polysulfone (PSU) and the like)

6

Coating glass outside-outside

7

Coating glass outside-inside

8th

Coating glass inside-outside

9

Coating glass inside-inside

10

Desiccant (molecular sieve)

11

light element

12

Electrical connection light element

13

fastener

14

reflector

15

light emission

16

Reflected light

17

Frame breakthrough inside

18

Interior (high molecular weight inert gas, eg argon, krypton, etc.)

19

20

21

22

23

EL light strips

24

LED strip

25

LED

26

27

28

29

30

31

32

Undercut for fastening a light element ( 11 )

33

34

35

Opening for LED

Claims (10)

Insulating glass element whose glass elements ( 2 . 3 ) is held parallel to each other by means of spaced-apart spacers at a distance from each other and whose interior is sealed by a sealing compound attached to the edges, wherein on the inside of the frame profile formed from the spacer ( 4 ) several light elements consisting of EL strips or LED strips or luminescent layers ( 11 . 23 . 24 . 25 ) are arranged, which in the interior ( 18 ) between the glass elements ( 2 . 3 ), characterized in that on the profile frame ( 4 ) a reflector ( 14 ) is arranged, that of the light element ( 11 . 23 . 24 . 25 ) reflected light ( 16 ) obliquely against the inside of the glass element ( 3 ). Insulating glass element according to claim 1, characterized in that the at least one light element ( 11 . 23 . 24 . 25 ) by cold glueing technique, hot melt gluing technique, crimping technique, snap technique, joining technique by screwing and the like assembly technique on the profile frame ( 4 ) is attached. Insulating glass element according to one of claims 1 or 2, characterized in that the light element ( 11 ) based on an LED strip ( 24 ) by means of a plastic profile with a fastener ( 33 ) and an opening for the LED ( 35 ) on the frame profile ( 4 ) is positioned and fastened by snap-action, crimping, pushing and the like techniques. Insulating glass element according to one of claims 1 to 3, characterized in that the frame profile ( 4 ) with an undercut ( 32 ) for the attachment of a light element ( 11 . 23 . 24 . 25 ) is trained. Insulating glass element according to one of claims 1 to 4, characterized in that the frame profile ( 4 ) with a laterally arranged undercut ( 32 ) for the attachment of a light element ( 11 . 23 . 24 . 25 ) is formed and on the inside of the profile frame ( 4 ) has a long-lasting luminescent layer. Insulating glass element according to one of claims 1 to 5, characterized in that the frame profile ( 4 ) with a laterally arranged undercut ( 32 ) for the attachment of a light element ( 11 . 23 . 24 ), wherein the light emission of the light element ( 11 . 23 . 24 ) is directed outwards or is formed at an angle. Insulating glass element according to one of claims 1 to 6, characterized in that the LED strip ( 24 ) by means of radial and / or SMD or SMT ( 25 ) and / or uncaused LED elements is formed and these photodiode components are mounted by means of soldering, welding, ultrasonic technology, laser technology and bonding technology on flexible and semi-flexible and rigid printed circuit board substrates and / or lead frames and interconnected depending on the technology in parallel or in series DC voltage of a few 1.5 volts to 48 volts are operated. Insulating glass element according to one of claims 1 to 7, characterized in that the glass element has graphically designed glass cutting elements and these are produced by means of mechanical milling equipment and / or by means of highly pulsed ablative laser systems and optionally additionally designed with colored glazing or translucent colors. Insulating glass element according to one of claims 1 to 8, characterized in that the glass element has a localized or an elongated recess for increasing the efficiency of the irradiation of an LED ( 25 ) and this recess is arranged on one of the front sides and / or flat sides of the glass element and with the frame profile ( 4 ) is covered. Insulating glass element according to one of claims 1 to 9, characterized in that the LED strip ( 24 ) in corresponding recesses of the profile frame ( 4 ) and with a good heat transfer to the frame profile ( 4 ) are attached to this.

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