Measuring the Flexural Strength of Ceramics at Elevated Temperatures – An Uncertainty Analysis

[1] Menčik, J. (1990). Strength and Fracture of Glass and Ceramics. Praha: SNTL. (in Czech)Search in Google Scholar

[2] Kozik, T., Rohač, J., Štubňa, I. (1990). A contribution to optimization of firing the electroporcelain insulators, I: Calculation of the temperature and stress fields in the insulator during its firing. Sklář a keramik, 40 (7), 208-212. (in Slovak)Search in Google Scholar

[3] Kozik, T., Rohač, J., Štubňa, I. (1990). A contribution to optimization of firing the electroporcelain insulators, II: Influence of the size and heating rate on mechanical stress. Sklář a keramik, 40 (8-9), 232-235. (in Slovak)Search in Google Scholar

[4] Štubňa, I., Trnik, A., Šin, P., Sokolař, R., Medveď, I. (2011). Relationship between mechanical strength and Young modulus in traditional ceramics. Materiali in Tehnologije, 45 (4), 375-378.Search in Google Scholar

[5] ASTM International. (2008). Standard test method for flexural strength of advanced ceramics at ambient temperature. ASTM Standard C1161-02c(2008)e1.Search in Google Scholar

[6] Vycudilik, P. (1978). Influence of the sample shape on mechanical strength of green clay material. Sklář a keramik, 28 (10), 301-308. (in Czech)Search in Google Scholar

[7] Netzch-Geratebau GmBH. Betriebsanleitung 10.68 402.E. (in German)Search in Google Scholar

[8] Štubňa, I., Trnik, A., Vozar, L. (2007). Thermomechanical analysis of quartz porcelain in temperature cycles. Ceramics International, 33 (7), 1287-1291.10.1016/j.ceramint.2006.04.024Search in Google Scholar

[9] Freund, F. (1967). Kaolinite-metakaolinite, a model of a solid with extremely high lattice defect concentration. Berichte Deutsche Keramische Geselschaft, 44 (N4), 5-13. (in German)Search in Google Scholar

[10] Štubňa, I., Kozik, T. (1997). Permeability of the electroceramics to gas and its dependence on the firing temperature. Ceramics International, 23 (3), 247-249.10.1016/S0272-8842(96)00034-XSearch in Google Scholar

[11] Kozik, T., Štubňa, I. (1981). Mechanical strength of ceramics in the dehydroxylation temperature region. Silikáty, 25 (3), 237-241. (in Slovak)Search in Google Scholar

[12] Štubňa, I., Trnik, A. (2007). Young’s modulus of porcelain mixture after firing in the dehydroxylation region. Ceramics - Silikáty, 51 (2), 102-105.Search in Google Scholar

[13] Štubňa, I., Šin, P., Trnik, A., Veinthal, R. (2013). Mechanical properties of kaolin during firing. Key Engineering Materials, 527, 14-19.10.4028/www.scientific.net/KEM.527.14Search in Google Scholar

[14] Joint Committee for Guides in Metrology. (2010). Evaluation of measurement data - Guide to the expression of uncertainty in measurement. JCGM 100:2008.Search in Google Scholar

[15] Timoshenko, S.P. (1956). Strength of Materials. New York: Van Nostrand. Search in Google Scholar