Mechanical Properties and Damage Evolution of Heated Granite Subjected to Liquid Nitrogen Cooling

To investigate the effect of liquid nitrogen on the granite failure process, the deterioration effect of liquid nitrogen on heated granite was investigated from experimental and theoretical perspectives. The mechanical properties of heated granite (25, 100, 200, 300, and 400 °C) after different cool...

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Published inApplied sciences Vol. 12; no. 20; p. 10615
Main Authors Zhou, Chunbo, Gao, Feng, Cai, Chengzheng, Zheng, Wenqi, Huo, Liupeng
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2022
Subjects
Cooling
damage
degradation
dissipated energy ratio
Energy dissipation
Experiments
Geothermal power
High temperature
liquid nitrogen
Mathematical functions
Mechanical properties
statistical damage constitutive model
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Abstract To investigate the effect of liquid nitrogen on the granite failure process, the deterioration effect of liquid nitrogen on heated granite was investigated from experimental and theoretical perspectives. The mechanical properties of heated granite (25, 100, 200, 300, and 400 °C) after different cooling treatments (air cooling and liquid nitrogen cooling) were investigated by uniaxial compression tests. The damage evolution analysis was performed by a statistical damage constitutive model and the dissipation energy ratio was newly defined. The results show that there is an increase in the uniaxial compressive strength of heated granite before 200 °C, which is due to the competitive relationship between the thermal cracking and crack closure. Liquid nitrogen cooling can deteriorate the mechanical properties of heated granite in terms of strength and deformability. At 400 °C, the reduction rates of compressive strength and stiffness between air cooling and liquid nitrogen cooling reached 32.36% and 47.72%, respectively. Liquid nitrogen cooling induces greater initial thermal damage and, consequently, leads to a greater degree of total damage before the peak stress and makes rock easier to be damaged. At 400 °C, the total damage at the peak stress increased from 0.179 to 0.587 after the liquid nitrogen cooling. The difficulty of damage can be quantified by the dissipation energy ratio. In addition, the deterioration of liquid nitrogen on granite is positively related to temperature. This study confirmed the deterioration effect of liquid nitrogen and promoting effect of temperature, providing a theoretical approach to the degradation mechanism of liquid nitrogen.
AbstractList To investigate the effect of liquid nitrogen on the granite failure process, the deterioration effect of liquid nitrogen on heated granite was investigated from experimental and theoretical perspectives. The mechanical properties of heated granite (25, 100, 200, 300, and 400 °C) after different cooling treatments (air cooling and liquid nitrogen cooling) were investigated by uniaxial compression tests. The damage evolution analysis was performed by a statistical damage constitutive model and the dissipation energy ratio was newly defined. The results show that there is an increase in the uniaxial compressive strength of heated granite before 200 °C, which is due to the competitive relationship between the thermal cracking and crack closure. Liquid nitrogen cooling can deteriorate the mechanical properties of heated granite in terms of strength and deformability. At 400 °C, the reduction rates of compressive strength and stiffness between air cooling and liquid nitrogen cooling reached 32.36% and 47.72%, respectively. Liquid nitrogen cooling induces greater initial thermal damage and, consequently, leads to a greater degree of total damage before the peak stress and makes rock easier to be damaged. At 400 °C, the total damage at the peak stress increased from 0.179 to 0.587 after the liquid nitrogen cooling. The difficulty of damage can be quantified by the dissipation energy ratio. In addition, the deterioration of liquid nitrogen on granite is positively related to temperature. This study confirmed the deterioration effect of liquid nitrogen and promoting effect of temperature, providing a theoretical approach to the degradation mechanism of liquid nitrogen.
Author Zhou, Chunbo
Huo, Liupeng
Cai, Chengzheng
Zheng, Wenqi
Gao, Feng
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  surname: Zhou
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  givenname: Liupeng
  surname: Huo
  fullname: Huo, Liupeng
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Snippet To investigate the effect of liquid nitrogen on the granite failure process, the deterioration effect of liquid nitrogen on heated granite was investigated...
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StartPage 10615
SubjectTerms Cooling
damage
degradation
dissipated energy ratio
Energy dissipation
Experiments
Geothermal power
High temperature
liquid nitrogen
Mathematical functions
Mechanical properties
statistical damage constitutive model
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Title Mechanical Properties and Damage Evolution of Heated Granite Subjected to Liquid Nitrogen Cooling
URI https://www.proquest.com/docview/2728423045
https://doaj.org/article/898049cd0c5d4c93a8d29af160a078c5
Volume 12
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