Post on 12-Aug-2020
Energy Efficient Lamination of Flat Glass via Radio Frequency Pressing
Shawn M. Allan*Morgana Fall, Dr. Holly S. Shulman
Ceralink Inc.
Ceralink Inc. develops advanced materials,green processes, and new products for industry.
Materials Science & Technology 2007Processing and Product Manufacturing:
Environmental Issues in the MaterialScience and Technology Industries
Green Materials and Processes
September 19, 2007 10:20 am
Roadmap
Products and marketsNeed for manufacturing alternativesApproach for low energy, green laminationBenefits and resultsConclusions
Products and MarketsLaminated flat glass, ceramics, safety plastics, composites
World laminated flat glass market is $11.7B, USA $2.7BGrowth (7-8%) driven by security and safety applications, regulations
Architectural GlassAuto Safety GlassHurricane and Seismic Protection GlassAerospace and Marine Glass and Composites
Transparent Armor and ShieldsLaminated CompositesSolar (Photovoltaic) PanelsMultilayer Ceramic Composites
Need: Manufacturing AlternativesEnergy Policy Act of 2005 (EPAct), Section 106
Reduce U.S. industry energy use 25% by 2017
Government vehicle ejection regulations (auto side windows)
Commodity pricing
Demand for low cost laminated photovoltaic (PV) panels
Growth of transparent ceramic armor markets
State of the art glass lamination
© 2007 DigiGlass Australasia Pty Ltd.
Laminators use 3 main types of interlayersPolyvinyl butyral (PVB)
Clear, printedEthylene vinyl acetate (EVA)
Clear, colored, opaqueThermoplastic Polyurethane (TPU)
Flat, curved, textured, or tempered glass
Processing requiresPre-processing rolling (de-airing)Autoclaving (PVB, TPU)Vacuum oven (EVA)
Large batches, 1 to 6 hour processes
RF Lamination TechnologyProduction method to make laminates,
faster and more efficient
1 minute cycleCuts energy up to 95%Heat interlayer directlyApply pressureReplace 3 steps with 1Prototype stage
GlassCeramicsSafety plastics Composites
RF Lamination TechnologyProduction method to make laminates,
faster and more efficient
1 minute cycleCuts energy up to 95%Heat interlayer directlyApply pressureReplace 3 steps with 1Prototype stage
GlassCeramicsSafety plasticsComposites
GlassVinylGlass
RF Lamination TechnologyProduction method to make laminates,
faster and more efficient
1 minute cycleCuts energy up to 95%Heat interlayer directlyApply pressureReplace 3 steps with 1Prototype stage
GlassCeramicsSafety plasticsComposites
Prelaminate
RF Lamination TechnologyProduction method to make laminates,
faster and more efficient
1 minute cycleCuts energy up to 95%Heat interlayer directlyApply pressureReplace 3 steps with 1Prototype stage
GlassCeramicsSafety plasticsComposites
Electrode/Platen
Electrode/Platen
RF Lamination TechnologyProduction method to make laminates,
faster and more efficient
1 minute cycleCuts energy up to 95%Heat interlayer directlyApply pressureReplace 3 steps with 1Prototype stage
GlassCeramicsSafety plasticsComposites
Electrode/Platen
Electrode/Platen
RF Energy & pressure
RF TechnologyRF field created between parallel electrodes
Electrodes double as press platens
Used widely for drying paper and wood, and sealing certain plastics
RF (1 to 300 MHz) dielectrically heats materialsat ISM allowed frequency, 27.12 MHz
Project ApproachExperimental
Vary glass and interlayer pairings to identify usesClear, tinted, metal coated glass, acrylic, polycarbonatePVB, printed PVB, EVA, and TPU interlayers
Vary RF power, time, and pressure10 – 20 Watts/cm²10 to 120 seconds10 to 100 psi
AnalysisVisual inspection for defectsDurability – boil and bake testsOptical transmissionEnergy analysis
Interlayers & Structural LayersPVB
DuPont Butacite® B5Solutia Saflex® RF41Solutia RS1220
Printed PVBDuPont SentryGlass Expressions®
EVASekisui S-LEC® EN FilmBridgestone EVASAFETM
Nanjing Kin Yong Fa coloredNanjing Kin Yong Fa opaque
TPUDeerfield Urethane Dureflex® A4700
Clear & Tinted GlassAutoWindow
Low-E Glass
Acrylic – Acrylite FF®
Polycarbonate – Lexan PC®
Feasibility ResultsVisual
InspectionOptical
TransmissionBake Test
Boil Test
Ambient Aging
Glass + Solutia PVB Yes
Edge haze
Yes
2 years
2 years
2 years
2 monthsEdge delam
2 months
2 months
2 months
5 months
Glass + DuPont SentryGlass PVB
Yes
Glass + Nanging EVA Yes Yes
5 months
Glass + Bridgestone EVA
Yes Yes Yes
Yes
Glass + DuPont PVB Yes
Glass + Sekisui EVA Yes Yes
Low-E + EVA Yes Yes
Glass + TPU Yes Yes
Polycarbonate + TPU Few bubbles
Acrylic + TPU Few bubbles
Feasibility Examples - PVB
DuPont Butacite® PVBin tinted glass
DuPont SentryGlass®
Printed PVB in clear glass
Solutia Saflex® PVB in clear and tinted glass
Feasibility Examples - EVA
Bridgestone EVASAFETM
Nanjing Kin Yong FaTransparent and Opaque EVA
Sekisui S-LEC® EN
Feasibility Examples - TPU
Polycarbonate Acrylic
Glass
Deerfield UrethaneDureflex® A4700
Low-E (metallized) glassGlass is metallized on one side2 panes laminated with EVASAFETM
Implications for use with photovoltaics and embedded sensors
RF Laminated Low-e Glass150 mm x 150 mm
Energy Efficiency
Efficiency improves as laminate area increases
Energy consumption of processIncreases linearly with area
DurabilityClear glass with Bridgestone EVASAFE and Sekisui S-LEC EVA
RF laminated glass was subjected to EU tests from EN ISO 12543-4:
•Boil, 100 °C, 2 h•Sekisui Passed•Bridgestone Edge Haze
•Bake, 130 °C, 2 h•Sekisui Passed•Bridgestone Passed
Samples were then observed for change ofclarity and defects
Optical TransmissionExample Transmission Spectra
for RF Laminated Glass
Typical average transmission of EVASAFE and glass
RF Laminated glass comparable to conventional process
Scale-up PlansRF lamination of
PhotovoltaicsLED and sensor containing filmsTransparent ceramic armor
Flat glass window size1 to 6 m2
Curved glassAutomotive sidelights & windshieldsArchitectural curved glass
Adhesion testing for comparison to autoclave/vacuum
Make RF lamination available to manufacturers
Summary of RF Glass LaminationMaterials comparable to autoclave and vacuum processed laminates
Energy saving technology1 minute semi-continuous process
1-6 hour batch process95% energy consumption reduction
Broad scope of useInterlayersStructural layersMetal coated glass
Path for further development and commercialization
Acknowledgements
This material is based upon work supported by the Department of Energy Office of Energy Efficiency and Renewable Energy
under Award Number DE-FG36-06GO16043.
Ceralink Contact InfoCeralink has applied for U.S. and international patents
for RF Press Lamination Technology
Contact: Shawn AllanSr. Materials Engineer
(518) 283-7733shawn@ceralink.com
Ceralink Inc. develops advanced materials,green processes, and new products for industry.