Features of interrelations between acoustic quality factor and strength of rock salt during fatigue cyclic loadings

Вознесенский, А. С.; Krasilov, M.N.; Kutkin, Ya.O.; Tavostin, M. N.; Osipov, Yu. V.

doi:10.1016/j.ijfatigue.2016.12.027

Cited by 58 publications

(13 citation statements)

References 9 publications

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“…More work is thus necessary to improve our understanding of the deformation mechanisms and internal structural changes linked to this notable change in mechanical properties. Voznesenskii et al (2017) also recorded a decrease in dynamic Young's modulus-calculated from ultrasonic velocity surveys-during cyclic loading conditions of similar amplitude, with a subsequent increase after more cycles were applied. The decrease in Young's modulus and rock sample strength was interpreted as a result of inner material arrangements.…”

Section: Impact Of Second-phase Content On Elastic Parametersmentioning

confidence: 96%

“…Yet, monitoring the elastic parameter variations (such as Young's modulus, Poisson's ratio, and Bulk modulus) at the early stage of the deformation behavior in relation to the different rock salt compositions would bring essential information on halite mechanical stability with respect to gas storage risks (Xiong et al 2015). Some authors show monitored acoustic emission from rock salt deformed under cyclic loading condition (Fan 2017;Voznesenskii et al 2017) and dynamic Young's modulus from velocities of the longitudinal P-and transverse S-waves through sounding of the samples (Voznesenskii et al 2017). This allows them to remotely observe the softening to hardening evolution of the halite when subjected to cyclic loading conditions.…”

Section: Introductionmentioning

confidence: 99%

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Impact of Second Phase Content on Rock Salt Rheological Behavior Under Cyclic Mechanical Conditions

2021

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Safe Underground Gas Storage (UGS) can be achieved in artificial, salt caverns to meet fluctuations in energy demand by providing adequate knowledge on rock salt when subjected to similar cyclic conditions. In this study, we performed cyclic mechanical tests on five rock salt samples with different types and amounts of second-phase mineral content. A confining pressure of 25 MPa was applied, whilst the axial stress was cycled between 4.5 and 7.5 MPa, at 0.5 kN/s loading rate, during 48 h (7200 cycles). The results demonstrate that high second-phase content such as anhydrite layering operates as a strength weakening agent by accommodating larger brittle deformation in comparison to samples with a lower content in secondary minerals. This rheological behavior is further exacerbated by the cycling mechanical conditions and recorded by a marked step on Young’s modulus and Poisson’s ratio value evolution. The microstructure analysis reveals how halite grains accommodate most of the deformation induced by the cyclic mechanical loading conditions through brittle deformation with microfracturing network development. Other structures from different deformation mechanisms are also discussed. Two types of new porosity are observed: (i) pores around isolated crystals of second-phase minerals as a result of grain rotation under cyclic mechanical deformation, and (ii) microcracks in areas with high concentration of secondary minerals (such as anhydrite, polyhalite, carnallite, or kieserite). This porosity change has strong implications for both the mechanical behavior of the material and its potential permeability.

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Section: Impact Of Second-phase Content On Elastic Parametersmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Impact of Second Phase Content on Rock Salt Rheological Behavior Under Cyclic Mechanical Conditions

2021

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“…Measurement of wave velocity is one of the most common (Rao and Ramana 1992;Lockner 1993;Meglis et al 1995;Brantut et al 2014;Voznesenskii et al 2017). Microscopic thin sections are also often provided (Ghamgosar and Erarslan 2016;Wang et al 2017).…”

Section: Crack Development and Measurementmentioning

confidence: 99%

“…Further research works are devoted to protect against environmental threats: designing tunnels against earthquakes (Hashash et al 2001), forecasting volcanic hazard (Kendrick et al 2013;Heimisson et al 2015), assessing the freeze-thaw cycles on tunnels built in hostile cold regions (Zhang et al 2004;Liu et al 2015), studying the ageing of pillars due to variations of water table level (Sorgi and De Gennaro 2011) or estimating the long-term stability of old monuments (Cattaneo and Labuz 2001;Jamshidi et al 2013) or buildings (Hale and Shakoor 2003) against weathering. Oil and gas storage, mainly in salt mines, is another application where cyclic loading is imposed to the environment by human activities by successive emptying and filling (Cosenza et al 1999;Wang et al 2015;Voznesenskii et al 2017). The use of old mines as lower reservoirs for pumped storage hydroelectricity also generates cyclic Abstract The purpose of this paper is to provide a comprehensive state of the art of fatigue and cyclic loading of natural rock materials.…”

Section: Introductionmentioning

confidence: 99%

Cyclic and Fatigue Behaviour of Rock Materials: Review, Interpretation and Research Perspectives

Cerfontaine¹,

Collin²

2017

Rock Mech Rock Eng

276

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“…Формирование и развитие разномасштабных трещин в механически нагруженном материале сопровождается выделением тепловой, акустической и электромагнитной энергии, связанным с разрывом межатомных связей, образованием новых поверхностей и сопутствующими процессами неупругого деформирования [1][2][3][4][5][6][7][8][9][10]. При этом пропорция диссипированной и запасенной в деформируемом материале энергии на различных этапах нагружения определяется как внутренними (состав, кристаллическая структура, дефектность), так и внешними (интенсивность и конфигурация приложенных нагрузок, температура) факторами [11][12][13][14].…”

Section: Introductionunclassified

Структурно-Энергетические Закономерности Накопления Повреждений При Деформировании Гетерогенного Материала

Дамаскинская¹,

Пантелеев²,

Корост³

et al. 2021

Физика Твердого Тела

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An experimental research of the defect accumulation under uniaxial loading of a natural heterogeneous material is carried out in this work. Defect formation process has been controlled using two non-destructive techniques (methods) such as acoustic emission (AE) and X-ray computed microtomography (CT). The combined use of these methods made it possible to find out correspondence between energy characteristics of AE accompanying the defect formation and the volume of these defects. It was found that total defect volume is lineary dependent on total AE signal energy. This fact corresponds to previously discovered phenomenological relationships for the sources of tectonic earthquakes. Mean defect size has been estimated based on obtained linear dependence. It was shown that mean linear size of defect does not exceed 100μm regardless of the assumptions about the defect shape.

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Features of interrelations between acoustic quality factor and strength of rock salt during fatigue cyclic loadings

Cited by 58 publications

References 9 publications

Impact of Second Phase Content on Rock Salt Rheological Behavior Under Cyclic Mechanical Conditions

Impact of Second Phase Content on Rock Salt Rheological Behavior Under Cyclic Mechanical Conditions

Cyclic and Fatigue Behaviour of Rock Materials: Review, Interpretation and Research Perspectives

Структурно-Энергетические Закономерности Накопления Повреждений При Деформировании Гетерогенного Материала

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