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References
Оглавление1 1 Slayter, G. and Thomas, J.H. (1938). Glass Fabric. US2,133,238. Owens‐Illinois Glass Company, Ohio.
2 2 ASTM D578/D578M‐05 (2011). Standard Specification for Glass Fiber Strands. West Conshohocken, PA: ASTM International www.astm.org.
3 3 Lowenstein, K.L. (1993). The Manufacturing Technology of Continuous Glass Fibres, 3e, 5–12–29–39. Amsterdam: Elsevier.
4 4 Li, H., Richards, C., and Watson, J. (2014). High performance glass fiber development for composite applications. Int. J. Appl. Glass Sci. 5: 65–81.
5 5 Longobardo, A.V. (2009). Glass fibers for printed circuit boards. In: Fiberglass and Glass Technology, Energy‐Friendly Compositions and Applications (eds. F.T. Wallenberger and P.A. Bingham), 175–196. New York: Springer.
6 6 Hausrath, R.L. and Longobardo, A.V. (2009). High‐strength glass fibers and markets. In: Fiberglass and Glass Technology, Energy‐Friendly Compositions and Applications (eds. F.T. Wallenberger and P.A. Bingham), 197–225. New York: Springer.
7 7 Li, H., Gu, P., Watson, J., and Meng, J. (2013). Acid corrosion and mechanism of E‐glass fibers: boron factor. J. Mater. Sci. 48: 3075–3087.
8 8 Wu, J. and Stebbins, J.F. (2013). Temperature and modifier cation field strength effects on aluminoborosilicate glass network structure. J. Non‐Cryst. Solids 351: 73–81.
9 9 Mysen, B.O. and Richet, P. (2005). Silicate Glasses and Melts Properties and Structure, Developments in Geochemistry 10, 231–285. Amsterdam: Elsevier.
10 10 Neuville, D.R., Cormier, L., and Massiot, D. (2006). Al coordination and speciation in calcium aluminosilicate glasses: effects of composition determined by 27Al MQ‐MAS NMR and Raman spectroscopy. Chem. Geology 229: 173–185.
11 11 Quintas, A., Charpentier, T., Majerus, O. et al. (2007). NMR study of a rare‐earth aluminoborosilicate glass with varying CaO‐to‐Na2O ratio. Appl. Magn. Reson. 32: 613–634.
12 12 Li, H. (2014). Alumina and silica sources for E‐glass fiber manufacturing‐melting energy aspect. Glass Tech.: Eur. J. Glass Sci. Tech. A 55: 7–13.
13 13 Dolan, M.D. and Misture, S.T. (2004). Analysis of glass batch reactions using in situ x‐ray diffraction, part III. Borosilicate glass batches. Glass Tech. 45: 212–219.
14 14 Conradt, R., Suwannathada, P., and Pimkhaokham, P. (1994). Local temperature distribution and primary melt formation in a melting batch heap. Glastech. Ber. Glass Sci. Technol. 67: 103–113.
15 15 Conradt, R. (2009). Thermodynamics of glass melting process. In: Fiberglass and Glass Technology, Energy‐Friendly Compositions and Applications (eds. F.T. Wallenberger and P.A. Bingham), 358–412. New York: Springer.
16 16 Beerkens, R.G.C., Laimbock, P., Faber, A.J., and Kobayashi, S. (1998). Interaction between furnace atmosphere and sulfate fined glass melts, 347–354. San Francisco, US: Proc. Inter. Cong. Glass XVIII.
17 17 Goldman, D. S. (1985). REDOX and sulfur solubility in glass melts. International Commission on Glass: Gas Bubbles in Glass, Charleroi, Belgium, pp. 74–91.
18 18 Agarwal, B.D. and Broutman, L.J. (1990). Analysis and Performance of Fiber Composites. New York: John Wiley & Sons, Inc.
19 19 Thomason, J.L. (2012). Glass Fibre Sizings: A Review of the Scientific Literature. James L Thomason: Charleston.
