LED-embedded glass: Difference between revisions
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==INTRODUCTION== |
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'''Transparent LED-embedded glass''' is a new [[composite material]] containing [[light-emitting diode]]s (LEDs). It is used as building material and as glass type for many different products. This new technology enables materials, new applications in electronics and architecture. Due to the use of a cold curing pick and place process, this technology is also related to electronics manufacturing and electronics engineering. This article is focusing on published<ref>[http://www.sun-tec.ch/downloads/gpd2009shavit.pdf | Download Article: D. Shavit, Transparent Electronic Interlayers, Proceedings of GPD Glass Performance Days, June 2009, pp. 177–180]</ref><ref>[http://www.sun-tec.ch/downloads/glassonline052007.pdf | Download article: D. Shavit; Developments of LEDs and SMD Electronics on transparent conductive polyesterfilms, Vacuum International 1/2007, Page 34-36]</ref> specifications enabling [[building material]]s which will meet security and legislation aspects of [[laminated glass]]. |
'''Transparent LED-embedded glass''' is a new [[composite material]] containing [[light-emitting diode]]s (LEDs). It is used as building material and as glass type for many different products. This new technology enables materials, new applications in electronics and architecture. Due to the use of a cold curing pick and place process, this technology is also related to electronics manufacturing and electronics engineering. This article is focusing on published<ref>[http://www.sun-tec.ch/downloads/gpd2009shavit.pdf | Download Article: D. Shavit, Transparent Electronic Interlayers, Proceedings of GPD Glass Performance Days, June 2009, pp. 177–180]</ref><ref>[http://www.sun-tec.ch/downloads/glassonline052007.pdf | Download article: D. Shavit; Developments of LEDs and SMD Electronics on transparent conductive polyesterfilms, Vacuum International 1/2007, Page 34-36]</ref> specifications enabling [[building material]]s which will meet security and legislation aspects of [[laminated glass]]. |
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==GALLERY== |
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<gallery> |
<gallery> |
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File:LEDGLASS1.jpg|LED embedded film for semitransparent glass application |
File:LEDGLASS1.jpg|LED embedded film for semitransparent glass application |
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</gallery> |
</gallery> |
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==COMPOSITE SPECIFICATION== |
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==Composite specification== |
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The LED–glass composite material may consist of using transparent metallized glass<ref>Hahn, T., EP0900971A1 [http://v3.espacenet.com/publicationDetails/biblio?DB=EPODOC&adjacent=true&locale=en_EP&FT=D&date=19990310&CC=EP&NR=0900971A1&KC=A1 "Lighting device containing LEDs on glass"]</ref> as electricity conductor. In this case the final composite specification will be: |
The LED–glass composite material may consist of using transparent metallized glass<ref>Hahn, T., EP0900971A1 [http://v3.espacenet.com/publicationDetails/biblio?DB=EPODOC&adjacent=true&locale=en_EP&FT=D&date=19990310&CC=EP&NR=0900971A1&KC=A1 "Lighting device containing LEDs on glass"]</ref> as electricity conductor. In this case the final composite specification will be: |
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* '''Bottom layer:'''...Metallised bottom glass |
* '''Bottom layer:'''...Metallised bottom glass |
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==THERMOPLASTICS== |
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The transparent thermoplastic material will usually show a quite similar light refractive index compared to glass. Typical thermoplastics used in the glass industry to produce these type of security glazings will consist of Thermoplastic Polyurethane<ref>Bayer Inc., US2006135728 [http://v3.espacenet.com/publicationDetails/biblio?CC=JP&NR=2006169536A&KC=A&FT=D&date=20060629&DB=EPODOC&locale=en_EP "Thermoplastic polyurethane (TPU) having good adhesion to glass "]</ref> (TPU), Ethyl-Vinyl-Acetate<ref>Bridgestone Inc., DE4308885(B4) [http://v3.espacenet.com/publicationDetails/biblio?CC=DE&NR=4308885A1&KC=A1&FT=D&date=19930923&DB=EPODOC&locale=en_EP "Laminated glass with thermoset film of (meth)acrylate or hydrocarbon resin – containing EVA and organic peroxide for high impact strength, penetration resistance and transparency"]</ref> (EVA) or Poly-Vinyl-Butyral<ref>Solutia Inc., WO03057478 [http://v3.espacenet.com/publicationDetails/biblio?DB=EPODOC&adjacent=true&locale=en_EP&FT=D&date=20080320&CC=IL&NR=162701A&KC=A "GLASS LAMINATION PROCESS AND APPARATUS"]</ref> (PVB). |
The transparent thermoplastic material will usually show a quite similar light refractive index compared to glass. Typical thermoplastics used in the glass industry to produce these type of security glazings will consist of Thermoplastic Polyurethane<ref>Bayer Inc., US2006135728 [http://v3.espacenet.com/publicationDetails/biblio?CC=JP&NR=2006169536A&KC=A&FT=D&date=20060629&DB=EPODOC&locale=en_EP "Thermoplastic polyurethane (TPU) having good adhesion to glass "]</ref> (TPU), Ethyl-Vinyl-Acetate<ref>Bridgestone Inc., DE4308885(B4) [http://v3.espacenet.com/publicationDetails/biblio?CC=DE&NR=4308885A1&KC=A1&FT=D&date=19930923&DB=EPODOC&locale=en_EP "Laminated glass with thermoset film of (meth)acrylate or hydrocarbon resin – containing EVA and organic peroxide for high impact strength, penetration resistance and transparency"]</ref> (EVA) or Poly-Vinyl-Butyral<ref>Solutia Inc., WO03057478 [http://v3.espacenet.com/publicationDetails/biblio?DB=EPODOC&adjacent=true&locale=en_EP&FT=D&date=20080320&CC=IL&NR=162701A&KC=A "GLASS LAMINATION PROCESS AND APPARATUS"]</ref> (PVB). |
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==PRODUCTION== |
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The specification mentioned above will typically be produced in following steps: |
The specification mentioned above will typically be produced in following steps: |
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* '''Bottom layer:'''..Glass |
* '''Bottom layer:'''..Glass |
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Within this last specification mentioned above, the 2 thermoplastic layers together with the LED interlayer will reach a total thickness of about 2 mm. The usually very economical PVB is the most used [[Laminated glass|lamination interlayer]]. Its lamination is based on a nip roller pre-heating step followed by an autoclaving process with a final stage ideally below 125 °C and 14 athmospheres. However, polyester has a better adhesion to [[Thermoplastics polyurethanes (TPU)|TPU]], to [[Ethylene-vinyl acetate|EVA]] or to EVASafe[http://www.bridgestone.com/products/diversified/evasafe/index.html EVASAfe], which are often laminated using simple vacuum tables. EVASafe contain some hygroscopic crosslinking agent, which will allow its partial crosslinking to active sites of the substrates. TPU may be used up to 125 °C. EVASafe should be used below 110 °C. |
Within this last specification mentioned above, the 2 thermoplastic layers together with the LED interlayer will reach a total thickness of about 2 mm. The usually very economical PVB is the most used [[Laminated glass|lamination interlayer]]. Its lamination is based on a nip roller pre-heating step followed by an autoclaving process with a final stage ideally below 125 °C and 14 athmospheres. However, polyester has a better adhesion to [[Thermoplastics polyurethanes (TPU)|TPU]], to [[Ethylene-vinyl acetate|EVA]] or to EVASafe[http://www.bridgestone.com/products/diversified/evasafe/index.html EVASAfe], which are often laminated using simple vacuum tables. EVASafe contain some hygroscopic crosslinking agent, which will allow its partial crosslinking to active sites of the substrates. TPU may be used up to 125 °C. EVASafe should be used below 110 °C. These transparent conductive thermoplastics may also be used for [[Transparent_heating_film|transparent heating]] of glass laminates. |
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==REFERENCES== |
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<!--- See [[Wikipedia:Footnotes]] on how to create references using <ref></ref> tags which will then appear here automatically --> |
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{{Reflist|2}} |
{{Reflist|2}} |
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Revision as of 16:39, 15 January 2012
INTRODUCTION
Transparent LED-embedded glass is a new composite material containing light-emitting diodes (LEDs). It is used as building material and as glass type for many different products. This new technology enables materials, new applications in electronics and architecture. Due to the use of a cold curing pick and place process, this technology is also related to electronics manufacturing and electronics engineering. This article is focusing on published[1][2] specifications enabling building materials which will meet security and legislation aspects of laminated glass.
GALLERY
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LED embedded film for semitransparent glass application -
Cuttable LED Strips -
Full-colour RGB LED-film laminated to 1x1 m floor glass -
LED glass stair
COMPOSITE SPECIFICATION
The LED–glass composite material may consist of using transparent metallized glass[3] as electricity conductor. In this case the final composite specification will be:
- Top Layer:...Standard glass
- Interlayer:...Transparent thermoplastic material like TPU, PVB or EVA
- Interlayer:..LEDs (light-emitting diodes)
- Bottom layer:...Metallised bottom glass
THERMOPLASTICS
The transparent thermoplastic material will usually show a quite similar light refractive index compared to glass. Typical thermoplastics used in the glass industry to produce these type of security glazings will consist of Thermoplastic Polyurethane[4] (TPU), Ethyl-Vinyl-Acetate[5] (EVA) or Poly-Vinyl-Butyral[6] (PVB).
PRODUCTION
The specification mentioned above will typically be produced in following steps:
- Vacuum sputtering of transparent conductive material on glass
- Cutting the glass to the final size
- Laser ablation of parts of the conductive material
- Mounting SMD LEDs on the glass by means of a pick-and-place process
- Lamination of the glasses according the specification mentioned above[citation needed]
Because most of the glass companies are not skilled to mount LEDs (light emitting diodes) onto metallized glass, it makes sense to locate the LEDs on a separate transparent conductive polymeric interlayer[7],[8],[9] which may be laminated by any glass lamination unit. In other words, the remaining process for glass lamination units will consist of laminating together standard glass using 2 layers of thermoplastic interlayers to sandwich ready to use LED-embedded films. This process will be quite similar for 3D curved LED–glass[10]. The final specification will be:
- Top layer:.. Glass
- Interlayer:..Transparent thermoplastic material like TPU, PVB or EVA
- Interlayer:..LED (light emitting diodes)on transparent conductive Polymer
- Interlayer:..Transparent thermoplastic material like TPU, PVB or EVA
- Bottom layer:..Glass
Within this last specification mentioned above, the 2 thermoplastic layers together with the LED interlayer will reach a total thickness of about 2 mm. The usually very economical PVB is the most used lamination interlayer. Its lamination is based on a nip roller pre-heating step followed by an autoclaving process with a final stage ideally below 125 °C and 14 athmospheres. However, polyester has a better adhesion to TPU, to EVA or to EVASafeEVASAfe, which are often laminated using simple vacuum tables. EVASafe contain some hygroscopic crosslinking agent, which will allow its partial crosslinking to active sites of the substrates. TPU may be used up to 125 °C. EVASafe should be used below 110 °C. These transparent conductive thermoplastics may also be used for transparent heating of glass laminates.
REFERENCES
- ^ | Download Article: D. Shavit, Transparent Electronic Interlayers, Proceedings of GPD Glass Performance Days, June 2009, pp. 177–180
- ^ | Download article: D. Shavit; Developments of LEDs and SMD Electronics on transparent conductive polyesterfilms, Vacuum International 1/2007, Page 34-36
- ^ Hahn, T., EP0900971A1 "Lighting device containing LEDs on glass"
- ^ Bayer Inc., US2006135728 "Thermoplastic polyurethane (TPU) having good adhesion to glass "
- ^ Bridgestone Inc., DE4308885(B4) "Laminated glass with thermoset film of (meth)acrylate or hydrocarbon resin – containing EVA and organic peroxide for high impact strength, penetration resistance and transparency"
- ^ Solutia Inc., WO03057478 "GLASS LAMINATION PROCESS AND APPARATUS"
- ^ D. Shavit: The developments of LEDs and SMD Electronics on transparent conductive Polyester film, Vacuum International, 1/2007, S. 35 ff
- ^ D. Shavit: Elektronische Komponenten in Glaslaminaten: Entwicklung, Stand und Ausblick, Glas, Architektur & Technik, 1/2007
- ^ SUN-TEC Swiss United Technologies Inc. Daniel Shavit, DE202007008410 "Translucent conductive Interlayer with SMD Surface Mounted Electronic Devices – LED embedded films"
- ^ Video with 3D curved laminated LED–glass