Mechanical behavior of marble exposed to freeze-thaw-fatigue loading

This study investigated the effects of freezing temperature under freeze-thaw cycling conditions on the mechanical behavior of sandstone. First, the sandstone specimens were subjected to 10-time freeze-thaw cycling treatments at different freezing temperatures (−20, −40, −50, and −60 °C). Subsequently, a series of density, ultrasonic wave, and static and dynamic mechanical behavior tests were carried out. Finally, the effects of freezing temperature on the density, P-wave velocity, stress–strain curves, static and dynamic uniaxial compressive strength, static elastic modulus, and dynamic energy absorption of sandstone were discussed. The results show that the density slightly decreases as temperature decreases, approximately by 1.0% at −60 °C compared with that at 20 °C. The P-wave velocity, static and dynamic uniaxial compressive strength, static elastic modulus, and dynamic energy absorption obviously decrease. As freezing temperature decreases from 20 to −60 °C, the static uniaxial compressive strength, static elastic modulus, dynamic strength, and dynamic energy absorption of sandstone decrease by 16.8%, 21.2%, 30.8%, and 30.7%, respectively. The dynamic mechanical behavior is more sensitive to the freezing temperature during freeze-thawing cycling compared with the static mechanical behavior. In addition, a higher strain rate can induce a higher dynamic strength and energy absorption.

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Fractional Stress Relaxation Model of Rock Freeze-Thaw Damage

Advances in Materials Science and Engineering ◽

10.1155/2021/3936968 ◽

2021 ◽

Vol 2021 ◽

pp. 1-8

Author(s):

Q. Liu ◽

W. Chen ◽

J. K. Guo ◽

R. F. Li ◽

D. Ke ◽

...

Keyword(s):

Stress Relaxation ◽

Fatigue Loading ◽

Element Model ◽

Model Parameters ◽

Rock Stress ◽

Relaxation Equation ◽

Freeze Thaw ◽

Thaw Cycle ◽

Nonlinear Stress ◽

Freeze Thaw Cycle

Freeze-thaw cycle is a type of fatigue loading, and rock stress relaxation under freeze-thaw cycles takes into account the influence of the freeze-thaw cycle damage and deterioration. Rock stress relaxation under freeze-thaw cycles is one of the paramount issues in tunnel and slope stability research. To accurately describe the mechanical behaviour of stress relaxation of rocks under freeze-thaw, the software element is constructed based on the theory of fractional calculus to replace the ideal viscous element in the traditional element model. The freeze-thaw damage degradation of viscosity coefficient is considered. A new three-element model is established to better reflect the nonlinear stress relaxation behavior of rocks under freeze-thaw. The freeze-thaw and stress relaxation of rock are simulated by ABAQUS, the relevant model parameters are determined, and the stress relaxation equation of rock under freeze-thaw cycle is obtained based on numerical simulation results. The research shows that the test results are consistent with the calculated results, indicating that the constitutive equation can better describe the stress relaxation characteristics of rocks under freeze-thaw and provide theoretical basis for surrounding rock support in cold region.

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Dynamic compressive strength of concrete damaged by fatigue loading and freeze-thaw cycling

Construction and Building Materials ◽

10.1016/j.conbuildmat.2017.07.046 ◽

2017 ◽

Vol 152 ◽

pp. 847-855 ◽

Cited By ~ 11

Author(s):

Jingzhou Lu ◽

Kongfeng Zhu ◽

Lizong Tian ◽

Li Guo

Keyword(s):

Compressive Strength ◽

Fatigue Loading ◽

Freeze Thaw ◽

Compressive Strength Of Concrete ◽

Dynamic Compressive Strength

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Excessively Wet Subgrade Improvement with 100% Industry By-Products for Heavy Traffic Pavement – II. Mechanical Behavior and Durability of Stabilized Soils

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.113-116.1429 ◽

2010 ◽

Vol 113-116 ◽

pp. 1429-1432

Author(s):

Xi Zhong Yuan ◽

Cheng Cheng Liu ◽

Wei Cui ◽

Fei Liu

Keyword(s):

Mechanical Behavior ◽

Heavy Traffic ◽

Dry Weight ◽

Strength Loss ◽

Systematic Investigation ◽

Treated Soil ◽

Freeze Thaw ◽

Volumetric Expansion ◽

Green Materials ◽

Compaction Degree

The workability of excessively wet subgrade can be effectively improved by using a “green materials” based entirely on industry byproduct of combination of fly ash (FA) with carbide lime (CL) and flue gas desulfurization gypsum (FGDG). This paper presents the results of a further systematic investigation on the mechanical behavior and durability of FA/CL/FGDG treated silt from Dezhou in Shandong province. FA, CL and FGDG were added at 3 levels in percentages of 8%-24%, 2%-6% and 1%-3% by dry weight of the soils, respectively. The unconfined compressive strength as well as splitting tensile strength (STS), volumetric expansion (VE), California bearing ratio (CBR), dry-wet cycles test and freeze-thaw cycles test were performed. The best strength of 0.802MPa was achieved for 24%FA/6%CL/1%FGDG treated soil, while the 16%FA/6%CL/1%FGDG treated soil also produce good strengths of 0.742MPa, after 7 days curing. STS keeps increasing with curing period in the first 8 weeks throughout the investigation. According to the VE test, a mellowing period may help prevent swelling from ettringite precipitation by letting these minerals form and hydrate before compaction. The FA/CL/FGDG treated soil has a better durability with strength loss ratio less than 15% after 10 wet-dry cycles, and the maximum weight loss around 25% after 10 freeze–thaw cycles. CBR decreases with decrease of compaction degree, but the values are still around 70 even in a poor compaction degree of 93%, meeting the general requirements of subgrade. So, if the silt subgrade is in excessively wet state and could not be compacted to the required density, the modified subgrade would still serve as a strong platform and could provide necessary support for pavement.

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