Evaluation of Elastic Modulus of Quartz Glass Tube at High Temperature by Modified Split Ring Method

doi:10.15541/jim20150002

Abstract

Abstract:

Quartz glass tubes are widely used in chemical, mechanical, optical, and other fields, especially for the cases of high temperature. However, scarcity of evaluation techniques of elastic modulus at high temperature causes a barrier for analysis of thermal stress and structure design. Although a split ring method has been used at room temperature, its application at high temperature is scarcely reported due to the difficulty of the deformation measurement. In this study, a combination of the split ring method and relative method was utilized to solve deformation measurement problem, thus evaluating the elastic modulus of quartz glass tubes at various temperatures. The results indicate that the elastic modulus datum increases from room temperature to 800℃, reaches the peak value of 87.20 GPa at 800℃, and then gradually decreases, and then sharply decreases when temperature higher than 1100℃. These results demonstrate that the quartz glass tube measurement by improved split ring method for determining high-temperature elastic modulus is accurate and reliable, which could be used to evaluate other brittle tubes at high temperature.

Key words: quartz glass tube, high temperature, elastic modulus, split ring, relative method

CLC Number:

TQ171

LIU Zhao, BAO Yi-Wang, WEI Chen-Guang, WAN De-Tian. Evaluation of Elastic Modulus of Quartz Glass Tube at High Temperature by Modified Split Ring Method[J]. Journal of Inorganic Materials, 2015, 30(8): 838-842.

Figures/Tables 7

Fig. 1 Schematic of split ring before and after loading

Fig. 2 Schematic of contrast disk and split ring sample before loading

Fig. 3 DSC curve of quartz glass powder

Fig. 4 Load-displacement curve of quartz glass split ring sample at 1000℃

Fig. 5 Elastic modulus of quartz glass split rings heated and loaded by one time from this test and published data from quartz glass[15]

Fig. 6 Elastic modulus of quartz glass split ring heated and loaded at the first to the third time

Fig. 7 Photograph of different quartz glass split rings, showing diameter changes after tests at different temperatures

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