Advanced glazing systems

• Autorzy: Eames P. C. , Zhao J. F. , Wang J. , Hyde T. , Fang Y.
• Konferencja: Renewable Energy : Innovative Idead and Building Technologies (17-20.05.2006 ; Polska-Bieszczady)
• Języki publikacji: EN

Abstrakty

EN

Energy use in building comprieses for most developed contries between 40 and 50% of total energy use. The glazing system installed into the building envelope influences significantly the heating/cooling, air conditioning and lighting loades and is a key component that must be addressed when minimising energy use. Most current low-heat loss glazing systems comprise more that two glass panes and are heavy, bulky and wide. A new vacuum glazing system produced at low temperatures at the University of Ulster allows heat loss coefficients of less than 1Wm-2K-1to be achieved using two glass panes only. Detailes of the current fabrication process and results of thermal charactersation are presented.

Słowa kluczowe

EN

advanced glazing systems

PL

szklenie

• Wydawca: Polskie Towarzystwo Energetyki Słonecznej PTES - ISES
• Czasopismo: Polska Energetyka Słoneczna
• Rocznik: 2006
• Tom: nr 1-2
• Strony: 27--30
• Opis fizyczny: Bibliogr. 10 poz., il.

Twórcy

autor

Eames P. C.

autor

Zhao J. F.

autor

Wang J.

autor

Hyde T.

autor

Fang Y.

• Centre for Sustainable Technologies, School of the Built Environment, University of Ulster, Northem Irleand, UK

Bibliografia

• 1. F. Zoller, 1913, Hollow pane of glass. German Patent Number 387655
• 2. S. J. Robinson and R. E. Collins, 1989, Evacuated windows theory and practice. In ISES Solar World Congress, Kobe, Japan
• 3. R. E. Collins and T. M. Simko, 1998, Current status of the science and technology of vacuum glazing. Solar Energy 62, 189
• 4. R. E. Collins, O. Asano, M. H. Katoh Misonou, and S. Nagasaka, 1999, Vacuum Glazing: Design options and performance capability. Glass in Buildings Conference, Bath UK, 221
• 5. D. K. Benson, L. K. Smith, C. E. Tracy, T. Potter, C. Christensen, Soule DE, Vacuum window glazings for energy-efficient buildings, Summary Report. Internal Report SERI/TP-212-3684, Solar Energy Research Institute Golden, Colorado USA
• 6. P. W. Griffiths, M. di Leo, P. Cartwright, P. C. Eames, P. Yianoulis, G. Leftheriortis, B. Norton, 1998, Fabrication of evacuated glazing at low temperature. Solar Energy 63, 243
• 7. T. J. Hyde, P. W. Griffths, P. C. Eames, B. Norton, 2000, Development of a novel low temperature edge seal for evacuated glazing. World Renewable Energy Congress VI, Brighton UK, 271
• 8. K. L. Agarwal and J. O. Betterton, 1974, On low temperature indium seals, Cryogenices 14, 520
• 9. B.C. Lewis, 1995, Sealing vacuum & cryogenic components with indium, CryoGas International, 21
• 10. Y. Fang, P. C. Eames, B. Norton, T. J. Hyde, 2006, Experimental validation of a numerical model for heat transfer in evacuating glazing. In press Solar Energy