Your search keyword '"Compressive Strength"' showing total 226 results

1. Effect of Public Fillers on Cement-Stabilized Recycled Mixes of Road Performance: Mechanical Properties, Microstructure, and Durability.

Author

Zhang, Ming, Cheng, Chen, Chiang, Kingsley, Wang, Xinxin, Zhu, Yazhi, and Luo, Hui

Subjects

*CONSTRUCTION & demolition debris, *MICROSTRUCTURE, *ROAD construction, *COMPRESSIVE strength, *DURABILITY

Abstract

In order to address the challenges of resource utilization posed by construction waste, the substitution of natural aggregate (NA) with public fill (PF) contents was investigated for load reclamation and road grassroots applications. A comprehensive assessment of road performance for the recycled mixture was conducted, focusing on parameters such as unconfined compressive strength, splitting strength, compressive resilience modulus, dry shrinkage, and frost resistance. Additionally, the impact of incorporating PF at various types and replacement ratios on the microstructure of cement-stabilized aggregate (CSA) was analyzed. The results indicated that the unconfined compressive strength of cement-stabilized recycled mixture with varying PF contents meets the base strength requirements for heavy, medium, and light traffic pavement on secondary and sub-secondary roads in China. Notably, the unconfined compressive strength and resilience modulus follow a similar pattern, reaching their peak at a 25% PF content. Microscopic examination reveals that an appropriate PF content leads to the predominant formation of C(N)-A-S-H, hydrotalcite, Ca(OH)2, and CaCO3 as paste reaction products. As the replacement of public fill increases from 0% to 25%, there is a gradual stacking of gel products, which enhances the compactness of the microstructure by cementing together unreacted particles. Consequently, this process reduces dry shrinkage strain and effectively mitigates the formation of reflection cracks. Applying large quantities of public fill to road construction can effectively deal with various waste accumulation problems and produce a novel road material with significant social, economic, and environmental benefits. [ABSTRACT FROM AUTHOR]

Published

2024

2. Comparative study on convolutional neural network and regression analysis to evaluate uniaxial compressive strength of Sandy Dolomite.

Author

Wang, Meiqian, Liu, Wenlian, Liu, Haiming, Xie, Ting, Wang, Qinghua, and Xu, Wei

Subjects

*CONVOLUTIONAL neural networks, *DOLOMITE, *REGRESSION analysis, *COMPRESSIVE strength, *MATERIALS compression testing, *WATER diversion

Abstract

Sandy Dolomite is a kind of widely distributed rock. The uniaxial compressive strength (UCS) of Sandy Dolomite is an important metric in the application in civil engineering, geotechnical engineering, and underground engineering. Direct measurement of UCS is costly, time-consuming, and even infeasible in some cases. To address this problem, we establish an indirect measuring method based on the convolutional neural network (CNN) and regression analysis (RA). The new method is straightforward and effective for UCS prediction, and has significant practical implications. To evaluate the performance of the new method, 158 dolomite samples of different sandification grades are collected for testing their UCS along and near the Yuxi section of the Central Yunnan Water Diversion (CYWD) Project in Yunnan Province, Southwest of China. Two regression equations with high correlation coefficients are established according to the RA results, to predict the UCS of Sandy Dolomites. Moreover, the minimum thickness of Sandy Dolomite was determined by the Schmidt hammer rebound test. Results show that CNN outperforms RA in terms of prediction the precision of Sandy Dolomite UCS. In addition, CNN can effectively deal with uncertainty in test results, making it one of the most effective tools for predicting the UCS of Sandy Dolomite. [ABSTRACT FROM AUTHOR]

Published

2024

3. The Effect of Demolition Concrete Waste on the Physical, Mechanical, and Durability Characteristics of Concrete.

Author

Tang, Jian, Cao, Jingying, Luo, Hua, Chen, Weihua, Jia, Zhiyou, Cunha, Sandra, and Aguiar, José

Subjects

CONSTRUCTION & demolition debris, CONCRETE durability, CONCRETE waste, ELECTRICAL resistivity, FLEXURAL strength, COMPRESSIVE strength

Abstract

With the development of urbanization, more and more construction and demolition waste (CDW) is generated. To enhance the mechanical properties and durability of concrete through the incorporation of recycled aggregate, the water/cement ratio was controlled to optimize the properties of concrete. In this work, one reference concrete with a water/cement ratio of 0.5 was prepared. The demolition concrete waste from East China was used, and 50% and 100% of the natural aggregates of the reference concrete were substituted. Furthermore, the water/cement ratio of concrete with 50% and 100% CDW was reduced to 0.3, and the superplasticizer was used to justify the workability of fresh concrete. Finally, the workability of fresh concrete was determined. After curing for 28 days, the density, water absorption, and resistance to chloride penetration of concrete were realized. The compressive and flexural strength were examined at 14 and 28 days, and the electrical resistivity test was conducted at 7, 14, and 28 days. The results indicate that with increasing CDW content, the mechanical properties and durability of concrete decreased. However, when the water/cement ratio decreased to 0.3, the concrete properties were optimized, such as the compressive strength and resistance to chloride penetration of concrete with 50% CDW increased by 74.2% and 28%, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

4. Effects of calcium impurities on the properties of magnesium oxychloride cement.

Author

Ning, Xinkuang, Zhang, Yong, and Wu, Chengyou

Subjects

*CALCIUM, *MAGNESIUM, *SALT lakes, *HEAT of hydration, *MAGNESIUM hydroxide, *MAGNESIUM oxide, *CALCIUM hydroxide

Abstract

China's salt lakes contain an abundance of magnesium resources as high-magnesium brine, a by-product of potash fertiliser production is often discharged into salt lakes, causing environmental damage. Magnesium oxide from salt-lake brine can be used to produce magnesium oxychloride cement (MOC), but the calcium impurities present in salt lakes affect the properties of MOC. To investigate the effects of these impurities, magnesium oxide was produced by calcining a magnesium hydroxide precursor. By adding calcium hydroxide or calcium chloride, the incorporated calcium impurities were 0, 5 and 10% by mass of magnesium oxide. The compressive strength, heat of hydration, composition of the hydration product phases and the pore structure development of MOC samples were evaluated. It was found that Ca2+ ions increased the early strength and the rates of setting and hardening of the MOC. However, the presence of calcium impurities did not change the hydration phase composition. This is primarily because the Ca2+ ions promoted the participation of magnesium oxide in the hydration reaction and enhanced the early strength of the MOC. The findings of this study demonstrate the technical feasibility of utilising magnesium resources from salt lakes to prepare magnesium oxide and apply it in the production of MOC. [ABSTRACT FROM AUTHOR]

Published

2024

5. Application of ANN in Construction: Comprehensive Study on Identifying Optimal Modifier and Dosage for Stabilizing Marine Clay of Qingdao Coastal Region of China.

Author

Bo, Qirui, Liu, Junwei, Shang, Wenchang, Garg, Ankit, Jia, Xiaoru, and Sun, Kaiyue

Subjects

LIME (Minerals), COMPRESSIVE strength, CLAY, ARTIFICIAL neural networks, POTASSIUM hydroxide, NONLINEAR analysis, ANALYTICAL chemistry

Abstract

Nowadays, the use of new compound chemical stabilizers to treat marine clay has gained significant attention. However, the complex non-linear relationship between the influencing factors and the unconfined compressive strength of chemically treated marine clay is not clear. In order to study the influence of various factors (dosage, type of stabilizer, curing age) on the unconfined compressive strength of solidified soil during chemical treatment, experiments were performed to determine the unconfined compressive strength of soft marine clay modified with various types of stabilizers. Further, an artificial neural network (ANN) model was used to establish a prediction model based on the unconfined compressive strength test data and to verify the performance. Sensitivity and optimization analyses were further conducted to explore the relative significance of parameters as well as the optimal dosage amount. Research has found that when the content of aluminate cement is 89.5% and the content of curing agent is 30%, the unconfined compressive strength significantly increases after 28 days of solidification, and the change in quicklime content has the greatest effect on the improvement in the unconfined compressive strength. The influence of modifiers on the unconfined compressive strength is in the order: potassium hydroxide > kingsilica > quick lime > bassanite. The values of each factor were obtained when the unconfined compressive strength was the maximum, which provided support for the optimization of the treatment scheme. The analysis of chemical treatment is no longer limited to the linear relationship according to the test results, which proves the feasibility of non-linear relationship analysis based on the artificial neural network. [ABSTRACT FROM AUTHOR]

Published

2024

6. Experimental Study and Application of Controlled Low-Strength Materials in Trench Backfilling in Suqian City, China.

Author

Xu, Jingmin, Luo, Qiwu, Tang, Yong, Zeng, Zhibo, and Liao, Jun

Subjects

*COMPRESSIVE strength, *TRENCHES, *POTTING soils, *SILT

Abstract

When backfilling narrow spaces, controlled low-strength materials (CLSM) can be used to achieve an effective backfilling effect. The pipeline engineering in Yahnghe Avenue of Suqian, China, provides a favorable on-site condition for the use of CLSM. However, no guidance exists for the determination of the material mixture ratio of CLSM for this geological condition. Laboratory tests were performed to investigate the basic physical parameters of excavated soil and the optimal mixture ratio of CLSM. Results indicate that the sand and silt account for 29.76% and 57.23% of the weight of excavated soil, respectively. As the water content increases (from 40% to 50%), the flowability of the CLSM approximately shows a linear increase (slumps values from 154.3 mm to 269.75 mm for 9% cement content), while its compressive strength shows a linear decreasing trend (from 875.3 KPa to 468.3 KPa after curing for 28 days); as the cement content increases (from 6% to 12%), the flowability approximately shows a linear decreasing trend (from 238.8 mm to 178.5 mm for 45% water content), while the compressive strength shows a linear increasing trend (from 391.6 KPa to 987.6 KPa after curing for 28 days). By establishing the relationship between compressive strength/flowability and the water–cement ratio, the optimal material ratio is determined to be 9% cement content and 40–43% water content. The engineering application results indicate that the use of CLSM can achieve efficient and high-quality backfilling effects for pipeline trenches. The findings of this research may provide a reference for the application of CLSM in fields with similar geological conditions. [ABSTRACT FROM AUTHOR]

Published

2024

7. Mechanical Characteristics and Damage Constitutive Model of Fiber-Reinforced Cement-Stabilized Soft Clay.

Author

Yan, Tiecheng, Zhang, Xingyuan, Cai, Sutong, Zhou, Zefeng, An, Ran, and Zhang, Xianwei

Subjects

GLASS fibers, CLAY, STRAINS & stresses (Mechanics), COMPRESSIVE strength, IMPACT strength, STRESS-strain curves, SWELLING of materials

Abstract

Marine soft clays are prevalent in coastal regions of China, giving rise to engineering challenges such as salt swelling, corrosion, and load bearing in foundations with soft soil. This study is dedicated to enhancing the mechanical properties of fiber-reinforced cement-stabilized soft clay (FCSSC) and revealing its strengthening mechanism. Uniaxial compression tests are performed to explore the impact of fiber length, fiber amount, and curing ages on mechanical behavior. The stabilization mechanisms of cement and glass fibers are explored through damage analyses and microscopy. Based on the experimental results, a damage constitutive model is formulated for FCSSC, and its validity is established by comparing fitting curves with testing curves. The results demonstrate a significant improvement in the mechanical properties of the stabilized soil, attributed to the synergistic effects of the cement and glass fibers. The growth rate of the unconfined compressive strength decreased with increasing curing ages. Notably, the fiber length significantly impacted the strength index, with short-chopped fibers playing a crucial role in strength enhancement. The compressive strength exhibited an initial increase followed by a decrease with rising fiber content, reaching a maximum between 0.3% and 0.4%. The bridging effect of the glass fibers proved effective in inhibiting compression crack expansion and mitigating structural damage of the soil sample. However, excessive fiber content or length led to improved local porosity, resulting in the deterioration of strength and deformation properties. The stress–strain curves fitted using the proposed damage constitutive model accurately reflected the stress–strain relationship and deformation characteristics of the FCSSC. [ABSTRACT FROM AUTHOR]

Published

2024

8. Formation mechanism and evolution model of buried hill reservoir in BZ19‐6 structural belt, Bozhong Sag, Bohai Bay, East China.

Author

Shi, Menglin, Xie, Xinong, Du, Xiaofeng, and Yu, Xiaohang

Subjects

*STRIKE-slip faults (Geology), *GAS condensate reservoirs, *WEATHERING, *NATURAL gas, *COMPRESSIVE strength, *ROCK deformation

Abstract

The BZ19‐6 structural belt is the largest buried hill oil‐gas‐bearing area recently discovered in Bohai Bay Basin. The formation and evolution of the buried hill reservoirs are complex. Presently, the development law and controlling factors of this reservoir is unclear. Based on 3D seismic, drilling data, thin section, and regional tectonic background, we explored the controlling factors and development law of the high‐quality buried hill reservoir. The results show that the buried hill reservoir can be vertically divided into a weathered glutenite zone, weathered fracture zone, internal fracture zone, and tight zone. The development of reservoir is mainly controlled by lithotypes, tectonic movement, and weathering. The rocks in the study area with low compressive strength, provided the material basis for the formation of fractures. The strongly reformed multi‐stage tectonic movements provides the external dynamics for the formation of fractures. Weathering further improved the physical properties of the reservoir. The buried hill reservoir is mainly distributed in the weathered fracture zone and internal fracture zone. Currently, natural gas mainly found in nearly E‐W‐trending and N‐S‐trending fractures. The nearly E‐W‐trending fractures are developed in the thrust nappe structure formed by N‐S‐trending extrusion in the Indosinian. The hinge zone of the structure is the main development area of fractures. The nearly N‐S‐trending fractures are associated with strike‐slip faults formed by sinistral strike‐slip stress in the Yanshanian. Under the background of NNE–SSW direction extensional stress during the Himalayan, early fractures were reactivated, opened and expanded, forming the reservoir space for later natural gas charging. [ABSTRACT FROM AUTHOR]

Published

2024

9. Research on Strength Model of Cemented Tailings Deposit Body in Underground Tailings Reservoir.

Author

Zhang, Xi, Wang, Hongjiang, Yang, Liuhua, and Bier, Thomas A.

Subjects

*COMPRESSIVE strength, *COST control, *SHEAR strength, *CONTENT analysis, *DIFFERENTIAL equations, *ROCK deformation, *INTERNAL friction

Abstract

Due to the lack of clarity in the strength design of underground tailings reservoirs, it is imperative to investigate the interaction between the tailings deposit body (TDB) and surrounding rock. Taking the TDB as the subject of analysis, a differential equation for vertical stress on the TDB is proposed, considering the stresses from the hanging wall of the surrounding rock and physical and structural parameters of the TDB. Considering the similarity between the underground tailings reservoir and one-step subsequent filling, in situ data of the one-step subsequent filling body from a mine was utilized to compare calculated values of the theoretical model. The resulting theoretical prediction error was less than 10%, thus verifying the reliability of the proposed model. According to the theoretical model analysis, the height of the TDB exerts the most significant influence on vertical stress, while the width and length of the TDB have a negligible impact. Moreover, internal friction angle has a more pronounced effect on vertical stress than cohesion force. A case study for a lead–zinc mine in China is presented in this work. Through uniaxial compressive strength and triaxial shear experiments, the key mechanical parameters of TDB at different ratios of cement to tailings are obtained. According to the theoretical model proposed herein, the distribution law of vertical stress in the height direction of TDB is determined for various ratios of cement to tailings. The original technical scheme of the mine has been optimized by using uniaxial compressive strength greater than vertical stress as the evaluation index, achieving both storage safety and cost reduction goals. [ABSTRACT FROM AUTHOR]

Published

2023

10. Synthesis and Characterization of Sustainable Eco-Friendly Alkali-Activated High-Content Iron Ore Tailing Bricks.

Author

Kang, Xiangyang, Li, Yanman, Li, Wei, Zhou, Yuxian, Cui, Jiarui, Cai, Baohua, Zi, Yong, Fang, Jing, Chen, Yongqing, Li, Senlin, and Kang, Xin

Subjects

IRON ores, BRICKS, PARTICLE size distribution, ENERGY consumption, CONSTRUCTION materials, FLEXURAL strength, ENVIRONMENTAL protection, IRON mining

Abstract

With the development of urbanization, the demand for bricks continues to increase. However, traditional brick production methods result in significant energy consumption and environmental pollution. In Hebei Province, China, historical mineral extraction activities have left behind substantial iron ore tailings (IOT). With the objective of recycling IOT resources and promoting ecological restoration and sustainable development, the feasibility of producing alkali-activated bricks using iron ore tailings was explored. This study primarily utilized IOT supplemented with ground granulated blast-furnace slag (GGBS) to successfully synthesize sustainable eco-friendly alkali-activated high-content IOT bricks. Experimental investigations were conducted to explore the effects of the raw material mixing ratio, content, and modulus of the alkaline activator, molding pressure, and grain size distribution on the strength. The research demonstrated that the IOT: GGBS ratio of 85:15 met the requirements of the Chinese JC/T422-2007 MU25 standard, resulting in compressive and flexural strengths of 31.72 MPa and 2.83 MPa, respectively. Increasing the alkali activator content enhanced the brick strength, with an optimal alkali activator modulus of 1 M. Moreover, the molding pressure significantly improved brick strength and also enhanced the particle-to-particle contact density. Bricks prepared using finer particle size IOT exhibited higher compressive strength, whereas flexural strength remained relatively unaffected by particle size distribution. Furthermore, a comprehensive analysis of the microstructure and alkali activation mechanism of IOT-GGBS bricks was performed using XRD, SEM, FTIR, and AFM techniques. The results indicated that IOT primarily acted as an aggregate and partially participated in the reaction, whereas GGBS reacted extensively, generating C-S-H gel and C-A-H, providing robust bonding strength. Additionally, the increase in GGBS content led to the partial disintegration of some IOT particles, forming more stable aggregates under the influence of the C-S-H gel. This study offers theoretical guidance for the efficient utilization of IOT in construction materials, thereby contributing to the promotion of sustainable development and environmental conservation. [ABSTRACT FROM AUTHOR]

Published

2023

11. Experimental Study on Macroscopic Mechanical Characteristics and Microscopic Pore Structure Evolution of Soil–Rock Mixture under Repeated Freeze–Thaw Cycles.

Author

Deng, Hongwei, Zhao, Bokun, Xiao, Yigai, and Tian, Guanglin

Subjects

FREEZE-thaw cycles, POROSITY, GRAPHITE mining, COMPRESSIVE strength, CRACK propagation (Fracture mechanics), ANGULAR distribution (Nuclear physics), MIXTURES

Abstract

The response characteristics of the mesostructure and macro-characteristics of the soil–rock mixture under repeated freeze–thaw action have an important influence on the safety and stability of the dump slope in low-temperature environments. In order to further understand the multi-scale response behavior of a soil–rock mixture under freeze–thaw cycles, this paper carried out indoor freeze–thaw cycles, uniaxial compression, and electrochemical impedance spectroscopy tests on a soil–rock mixture taken from a graphite mine dump in Jixi City, Heilongjiang Province, China. Combined with the simulation calculation of discrete element numerical software (PFC2D 7.0), the effects of freeze–thaw cycling on electrochemical impedance spectrometry (EIS) mesoscopic parameters, uniaxial compressive strength, and crack propagation of soil–rock mixtures were analyzed. The intrinsic relationship between mesoparameters and macroscopic mechanical properties was established. The results showed that as the number of freeze–thaw cycles increases from 0 to 15, the mesopores inside the soil–rock mixture gradually increase, and the angular similarity of distribution characteristics increases by 5.25%. The uniaxial compressive strength and the peak secant modulus increase exponentially with the increase in the number of freeze–thaw cycles, the uniaxial compressive strength decreases by 47.62%, and the peak secant modulus decreases by 75.87%. The peak strain and pore compaction stage showed an exponential increase and an increasing trend, respectively, and the peak strain increased from 2.115% to 4.608%. The failure mode was basically similar in different cycles; the failure cracks extended from the corners to the middle and lower parts before the failure finally occurred. The types of failure cracks were mainly tensile cracks, followed by tensile shear cracks and the fewest compression shear cracks. The similarity and uniaxial compressive strength conformed to a good linear relationship with the number of freeze–thaw cycles, with the uniaxial compressive strength decreasing linearly with the increase in similarity. [ABSTRACT FROM AUTHOR]

Published

2023

12. Effect of Phosphoric Acid on the Preparation of α-Hemihydrate Gypsum Using Hydrothermal Method.

Author

Zhang, Jianwu, Wang, Xiao, Hou, Pengtao, Jin, Biao, Zhang, Xiaoting, and Li, Zhixin

Subjects

*PHOSPHORIC acid, *COMPRESSIVE strength, *WATER consumption, *PHOSPHOGYPSUM, *CITRIC acid, *GYPSUM

Abstract

The effects of phosphoric acid (H3PO4) in pressurized aqueous solution on the dehydration of CaSO4·2H2O to form α-hemihydrate gypsum (α-HH) phase and the regulation of crystal shape were studied in this paper in order to provide guidance for the low-cost and high-value utilization of phosphogypsum. The results showed that H3PO4 can significantly accelerate the formation rate of the α-HH phase and that it did not participate in the formation of the α-HH phase in the form of eutectic phosphorus during crystalline phase transformation. In terms of crystal shape regulation, H3PO4 can impact the effect of a citric acid crystal regulator on α-HH crystal shape regulation. The more H3PO4 added, the greater the aspect ratio of α-HH. Accordingly, the water consumption and 2 h dry compressive strength of α-HH products were gradually increased and decreased with an increase in H3PO4 content, respectively. Despite this, the compressive strength of α-HH can still meet the requirements of the α20 grade in JC/T 2038-2010 "α High Strength Gypsum" in China when the H3PO4 content was limited to less than 0.4%. [ABSTRACT FROM AUTHOR]

Published

2023

13. The Preparation of Active Support-Based Sealing Material and Sealing Effect Analysis.

Author

Zhang, Jianguo, Zhou, Yuejin, Zhou, Xin, Wang, Man, Liu, Shuaitao, Yang, Zhanbiao, and Zheng, Lihui

Subjects

GAS leakage, INTERNAL friction, STRENGTH of materials, COMPRESSIVE strength, PERMEABILITY, DRAINAGE, ROCK deformation

Abstract

To improve the effect of gas drainage, with the aim of overcoming the problem of air leakage of conventional sealing materials, this study proposed the concept of gas drainage borehole sealing with active support and developed a new type of sealing material with the properties of permeability, fluidity, expansibility, early strength and compressive resistance through orthogonal tests. Using a specially designed active support testing device, this study analyzed the development law of borehole fracture under the action of active support force, which was then verified via field tests at a mine in Henan Province, China. The results show that the higher the expansion rate, the smaller the internal friction angle and cohesion, which is reflected in the sharp decline in the peak strength of the sealing material. The active support force of the sealing material has a significant time effect. It increases rapidly at first, before its growth rate slows down and tends toward a certain value. The greater the active support force provided by the sealing material, the smaller the radius of the plastic zone and breakage zone; this observation is also true of the displacement around the borehole. The active support force of sealed boreholes can effectively inhibit the development of cracks around the hole and reduce the generation of gas leakage channels. Under the action of the same burial depth and active support force, the larger the mechanical parameters of rock, the smaller the radius of the plastic zone and the breakage zone, as well as the smaller the displacement around the borehole. As has been proven by engineering practice, under the same conditions, the gas drainage concentration of the new sealing material is 47.5%, which is 84.8% higher than that of the original sealing material. [ABSTRACT FROM AUTHOR]

Published

2023

14. Effects of Steel Slag Powder as A Cementitious Material on Compressive Strength of Cement-Based Composite.

Author

Sheng, Guohua, Li, Chao, Jin, Shengji, and Bai, Quan

Subjects

*COMPRESSIVE strength, *STRENGTH of materials, *SLAG, *CEMENT composites, *STEEL, *FLY ash

Abstract

The utilization rate of steel slag in China is far behind that of developed countries. The annual output of steel slag is still increasing, resulting in a large amount of accumulation, causing environmental pollution. This paper summarizes and analyzes the relevant research on steel slag powder (SSP) as a cementitious material, studies the effect of SSP replaces cement as single or multiple admixtures, with different specific surface areas, and the amount of activator on the compressive strength of cement-based material. The results show that due to the lower content of active substances in SSP compared to cement, the strengths decrease with the increase of the replacement ratio R, which is the ratio of SSP to cement. R = 30% is important for replacing cement with single SSP. When replacing cement with the mixture of SSP and slag/fly ash, the strengths of most groups decrease with the increase of the mix replacement ratio Rc. The decreasing trend is not obvious due to the pozzolanic effect. There is an optimal dosage for using a single activator to activate SSP. The effect of using multiple activators in combination is better than that of single one. The strength increases with the increase of the specific surface area (SSA) of SSP. However, if the SSA is too high, it will not only increase the preparation cost, but also reduce the increase in strength due to the agglomeration effect of SSP. The optimal range of specific surface area SSA is 400 m2/kg~500 m2/kg. With the increase of age t, the compressive strength increases. The effect of the curing methods on the compressive strength is hot and heat curing > standard curing > natural curing. [ABSTRACT FROM AUTHOR]

Published

2023

15. Effects of Growth Ring Width, Height from Tree Base, and Loading Direction on Transverse Compression of Plantation Japanese Larch Wood.

Author

Zhang, Fenghao, Wang, Sidong, Jiang, Jinghui, Chen, Dongsheng, and Zhou, Haibin

Subjects

WOOD, TREE height, TRANSVERSE strength (Structural engineering), LARCHES, COMPRESSIVE strength

Abstract

This study aimed to investigate the effects of growth ring width, height from the tree base, and loading direction on the transverse compressive strength of Japanese larch wood, which is commonly used in wood structures in China. Plantation wood is often used to replace natural forest woods for reconstruction purposes, despite significant differences in properties (e.g., growth rings, density, strength) between them. The ends of transversely compressed wood members in such structures are prone to damage by breaking or crushing. A transverse compressive test was conducted following Chinese national standards, which revealed the following key findings. (1) There was a significant difference in the transverse compressive strength of wood with different growth ring widths (p < 0.05). The radial and slant compressive strength of wood increases with growth ring width, while the tangential compressive strength decreases as growth ring width increases. (2) The transverse compressive strength of wood decreases as the height from the tree base increases. The radial, tangential, and slant compressive strength at a lower height were 18.39%, 22.58%, and 18% higher than those at a greater height in the stem, respectively, with significant differences at the 0.05 level. (3) The load–displacement curve of Japanese larch wood under radial and slant compression follows a "three-segment" form. In contrast, the load–displacement curve of tangential compression is a continuous curve that drops sharply upon reaching its highest point. (4) There is a significant difference in the transverse compressive strength of Japanese larch wood in different loading directions when growth ring width and height from the tree base are constant (p < 0.05), which fall into order as tangential > radial > slant. [ABSTRACT FROM AUTHOR]

Published

2023

16. Recovered soda residue as alkaline activator of furnace slag: geopolymer prepared from furnace slag incorporated with soda residue and its reuse in composite cement.

Author

Wang, Qiang, Zhang, Tao, Wu, Peng, and Lyu, Xianjun

Subjects

CEMENT composites, SLAG, FURNACES, INORGANIC polymers, COMPRESSIVE strength, HYDRATION

Abstract

The accumulation of soda residue (SR) poses a consequential threat to the environment because of the absence of effective methods for treating them on a large scale. SR is composed of NaCl, CaSO4·0.5H2O, and Ca(OH)2 in addition to CaCO3, which can be potentially used to replace reagent-grade alkaline activators for activating furnace slag (FS). This work investigates the effect of SR addition on the hydration mechanism of FS by preparing geopolymer from FS and SR. The geopolymer's compressive strength, initial pH value, and hydration products (including yield and morphology) were analyzed; its activity index was also investigated. The analysis results show that the pozzolanic activity of FS was stimulated using SR as alkaline activator. In the presence of SR, FS dissociated to form [SiO4]4− and [Al2O4]2− first. Then, it reacted with Ca2+, OH−, Na+, Cl−, and SO2 − 4 to form lamellar C(N)–S–H, needle AFt, and platelet Fs. Upon the addition of 70 wt.% SR to 30 wt.% FS, the hydration products reach the highest yield, leading to optimum compressive strengths of 3.43 and 8.84 MPa at 2 and 30 d, respectively. Furthermore, although the activity index of the geopolymer prepared from 70 wt.% SR and 30 wt.% FS is only 50.95%, 0–20 wt.% geopolymer can be used as an additive to prepare a 32.5-grade composite cement. This work realized the large-scale resource management of continuously discharged SR in support of China's double carbon policy. [ABSTRACT FROM AUTHOR]

Published

2023

17. Study on Instability Characteristics of the Directional Borehole on the Coal-Seam Roof: A Case Study of the Tingnan Coal Mine.

Author

Wang, Zhie, Yang, Xin, Wang, Gongda, and Gong, Haiwen

Subjects

COAL mining, ROCK deformation, DIRECTIONAL drilling, MATERIAL plasticity, COMPRESSIVE strength, BOREHOLES

Abstract

Directional long drilling on the roof is an effective gas control measure in the goaf, but there is little research on the stability of the surrounding rock. In this study, the geological conditions of the #4 coal seam in the Tingnan Coal Mine, Shaanxi Province, China taken as the application background, and the deformation characteristics of boreholes under four typical coal and rock conditions were first analyzed based on the Universal Distinct Element Code (UDEC) numerical simulation. Secondly, the stress, strain, and plastic deformation of the rock surrounding the borehole with different diameters were carried out using the Fast Lagrangian Analysis of Continua 3D (FLAC 3D). The effect of the casing on the stability of the borehole was also simulated. The results showed that the borehole stability of coal and mudstone was lower than that of fine-grained sandstone and coarse-grained sandstone. The larger the borehole diameter, the lower the stability. The borehole tended to be unstable, especially when the diameter was 160 mm and 200 mm. Traditional pipes can provide some protection, but for large boreholes, the protection is poor. Based on the above research, uniaxial compression tests were carried out on various internal support tubes, such as 'line-shaped', 'Y-shaped', and 'cross-shaped'. The results showed that the cross-shaped pipe had the highest compressive strength, which was 4–5 times that of the other types of protective pipe and had a good protective effect. The research results can provide reliable technical support for the protection of directional boreholes on roofs through strata and have important implications for the popularization and application of the directional long borehole technique. [ABSTRACT FROM AUTHOR]

Published

2023

18. Study on the Compressive and Tensile Properties of Gneiss Outcrop of Bozhong 196 Gas Field in China.

Author

Yang, Lianzhi, Niu, Tong, He, Fanmin, and Song, Zhiyong

Subjects

*POISSON'S ratio, *GNEISS, *ELASTIC modulus, *TENSILE strength, *GAS fields, *COMPRESSIVE strength

Abstract

In this paper, based on the gneiss outcrop of Bozhong 196 gas field in China, uniaxial compression and Brazil splitting tests were conducted by using cores of different orientations. The following compression properties were studied: the elastic compression modulus, Poisson's ratio and compressive strength of the gneiss outcrop. The following tensile properties were studied: the tensile modulus, the tensile strength and peak energy rate of gneiss outcrop. The results demonstrate the following: (1) The elastic compression modulus, compressive strength, tensile strength and peak energy rate of gneiss specimens with horizontal core-taking are greater than those with vertical core-taking. (2) The elastic compression modulus, Poisson's ratio and compressive strength of horizontally cored gneiss specimens are 29.688–45.760 GPa, 0.186–0.386, and 174.94–147.80 MPa, respectively; the elastic compression modulus, Poisson's ratio and compressive strength of the vertical gneiss specimens are 26.541–32.602 GPa, 0.429–0.476 and 169.37–134.46 MPa. (3) The tensile modulus of the horizontal gneiss specimens is 4.93–5.98 GPa. The tensile modulus of the vertical gneiss specimens is 0.96–2.11 GPa. The tensile modulus of the horizontal gneiss specimens is five times that of the vertical gneiss specimens. The elastic compression modulus of gneiss is 5–20 times that of the tensile modulus. (4) The tensile strength and peak energy rate of horizontally cored gneiss specimens are 14.33–17.55 MPa and 2598.67–4049.53 J/m2, respectively. The tensile strength of the vertical gneiss specimens is 6.12–9.65 MPa, and the peak energy rate is 715.74–1515.30 J/m2. (5) There is a good linear relationship between the peak energy rate and tensile strength of gneiss. The research results can provide a scientific and reasonable reference for in situ fracturing of Bozhong 196 gas field. [ABSTRACT FROM AUTHOR]

Published

2023

19. 高放废物地质处置用低 pH 胶凝材料及其基本性能试验研究.

Author

路 威, 赵卫全, 陈 亮, 张金接, 周建华, and 王 驹

Subjects

MORTAR, FLY ash, WATER salinization, RADIOACTIVE wastes, POZZOLANIC reaction, PORTLAND cement, COMPRESSIVE strength, RADIOACTIVE waste disposal, SILICA fume

Abstract

Copyright of Atomic Energy Science & Technology is the property of Editorial Board of Atomic Energy Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

20. Preparation and Hydration Properties of Steel Slag-Based Composite Cementitious Materials with High Strength.

Author

Xu, Zhiming, Ma, Ying, Wang, Jiahao, and Shen, Xiaodong

Subjects

*COMPOSITE materials, *STRENGTH of materials, *CEMENT composites, *FLUE gas desulfurization, *HYDRATION, *HEAT of hydration

Abstract

Steel slag (SS) has been largely discharged but little utilized, causing an environmental problem in China. In this paper, SS-based composite cementitious materials with high strength were prepared by the high volume of SS (≥40%), granulated blast-furnace slag (GBFS), fly ash (FA), flue gas desulfurization gypsum (FGDG) and cement to promote the effective utilization of SS. The hydration and hardening properties were studied through setting time, compressive strength, length change, isothermal calorimetry (IC), X-ray diffraction (XRD), mercury intrusion porosimetry (MIP), and scanning electron microscopy equipped with energy dispersive spectroscopy (SEM-EDS) tests. The results show that SS-based composite cementitious material exhibited a lower hydration heat release, an appropriate setting time, and volume stability. The SS cementitious material with 40% SS could obtain high strength of over 65 MPa at 28 days and 80 MPa at 90 days. The strength value of > 60 MPa is present in the binder, with 50% SS at 56 days. GBFS promotes hydration reactions and the formation of AFt and C-(A)-S-H gel, thus enhancing compressive strength. FA has a beneficial effect on later strength. The small and fine pore structures contribute to the development of strength. The main hydration products of SS composite cementitious materials are C-(A)-S-H gel, and ettringite (AFt), with less Ca(OH)2. The C-(A)-S-H gel with a lower Ca/Si ratio and a higher Al/Ca ratio in cementitious material, promotes mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2023

21. An effective control method of rock burst induced by shear instability of fault structure under complicated geological conditions.

Author

Xiao, Zhimin, Gu, Shitan, Zhang, Yunzhao, and Wang, He

Subjects

*ROCK bursts, *ROCK deformation, *COAL mining, *MINING methodology, *COMPRESSIVE strength, *PROCESS mining, *GAMMA ray bursts

Abstract

With the increase of mining depth, disaster degree of rock burst in fault-controlled area is becoming more and more serious. To analyze mechanism and control method of fault rock burst, No. 3316 mining face controlled by No. 3DF56 fault in Jining mine, China, is selected as case study. First, by analysis of general situation of the mining face, mechanical characteristics of coal rock, and micro-seismic events, it is determined that the coal seam has the possibility of rock burst in the process of the face mining towards the fault. Second, based on strength theory of rock, criterion of fault shear instability is obtained, and influence of cohesion and friction angle on the stability of fault is analyzed, and it is concluded that improving the cohesion of rock can control the fault slip. Third, by borehole detection recorder, it is determined that fracture areas of fault surrounding rock distribute in the range of 0–4 m from the surface of roadway surrounding rock and 0–5.0 m from the fault. Finally, control method of "precise grouting to couple shallow and deep boreholes" is introduced, and the grouting borehole scheme is optimized. Field test results show that the method can improve the compressive strength of coal rock and distribution laws of micro-seismic events, weaken the possibility of fault slip, effectively control the deformation of roadway surrounding rock and improve the control effect of rock burst. It can provide a reference for other coal mines with similar geological conditions. [ABSTRACT FROM AUTHOR]

Published

2023

22. Creep Behavior and Its Prediction of Saturated Weakly Cemented Medium-Grained Sandstone under Multiaxial Loadings.

Author

Gu, Qingheng, Zhao, Guangming, Meng, Xiangrui, Sun, Jian, Cheng, Xiang, Xu, Wensong, and Zhang, Ruofei

Subjects

*SANDSTONE, *AXIAL loads, *EVOLUTION equations, *ENERGY dissipation, *COMPRESSIVE strength, *CREEP (Materials), *ROCK deformation

Abstract

Weakly cemented medium-grained sandstone in Ordos mining area of China is widely distributed under phreatic water. The creep behavior of saturated rock is important for the stability of water-resisting strata. In this paper, creep mechanical properties of saturated medium-grained sandstone were studied by triaxial rheological test. The results showed that medium-grained sandstone only shows attenuation creep and stable creep under low stress level, and accelerated creep occurs when axial load reaches about 75% of instantaneous compressive strength. The rock samples exhibit volume dilatancy under most loading levels and finally shear fracture. The failure mechanism is the dislocation separation of mineral particles. Based on the energy dissipation theory, the damage evolution equation was modified and introduced into the Burgers model, which can accurately describe the rheological behavior of saturated medium-grained sandstone. The modified model was used to predict the crack initiation time under different deviatoric stresses, which can provide guidance for early warning of water-resisting rock stability. [ABSTRACT FROM AUTHOR]

Published

2023

23. Material Selection for the Hydrophobic Cushion Layer Applied to Earthen Sites in Northwest China.

Author

Zhang, Qiyong, Chen, Wenwu, and Wu, Guocheng

Subjects

*EDIBLE fats & oils, *POLYVINYL alcohol, *RICE oil, *WATER vapor, *COMPRESSIVE strength, *SAND dunes

Abstract

Earthen sites with important historical, cultural, artistic, social, and scientific values have been seriously damaged. Basal erosion, which is caused by soluble salts, water runoff, and sand-driving wind, is an extremely threatening erosion pattern for earthen sites. A cushion layer which has a damp-proofing function and good physical and mechanical properties can effectively decrease basal erosion. The primary aim of this study is to investigate material selection for the hydrophobic cushion layer for earthen sites in northwest China. The results indicate that cooked tung oil and sticky rice liquid, traditionally used in China, cannot meet the fundamental requirements of sufficient hydrophobicity for the cushion layer. Although polyvinyl alcohol (PVA) solution and tung oil exhibit similar properties in terms of soil hydrophobicity, water vapour permeability, water resistance, surface hardness, and colour difference for samples with 0.0-1.0% content, the PVA solution is significantly better than tung oil in unconfined compressive strength, deformation modulus, wave velocity, and viscosity. Therefore, the PVA solution should be preferentially selected as a hydrophobic cushion layer material according to the results of this work. When the mixing method is adopted, 0.6-1.0% PVA content is the best choice. [ABSTRACT FROM AUTHOR]

Published

2023

24. Macro and micro experimental study on solidification of Yellow River silt based on different biomineralization technologies.

Author

Wang, Yuke, Jiang, Rui, Jiao, MeiJu, Cao, Tiancai, and Yu, Xiang

Subjects

MICROTECHNOLOGY, SILT, BIOMINERALIZATION, SOLIDIFICATION, SCANNING electron microscopes, SPECIFIC gravity, COMPRESSIVE strength

Abstract

A large amount of silt is deposited in the riverbed of the middle and lower reaches of the Yellow River, in China. The silt content in the Yellow River silt is relatively high and the clay content is relatively low, the engineering application is limited. Based on the Yellow River silt characteristics, it was solidified by microbial induced calcite precipitation (MICP) and enzyme induced calcite precipitation (EICP) technology in this paper. Unconfined compressive strength test, CaCO3 content test and scanning electron microscope test were used. The effects of cement solution concentration (C), grouting time (N) and relative density (Dr) on the solidification of the Yellow River silt were considered, and the advantages and disadvantages of MICP technology and EICP technology were compared. The test results show that the effect of cement solution concentration on unconfined compressive strength and CaCO3 production of the Yellow River silt is significantly higher than that of grouting times N and relative compactness Dr, and the effect of relative compactness Dr can be ignored. When the cement solution concentration C and grouting times N are fixed, the compressive strength of EICP solidified samples is always greater than that of MICP solidified samples. The cement solution concentration C = 1 mol/L and the grouting times N = 8, the maximum compressive strength of the Yellow River silt solidified by MICP and EICP technology is 674.98 kPa and 954.65 kPa, respectively. The CaCO3 crystal generated in the sample was attached to the surface of silt particles, and the pores were also filled with CaCO3 crystal and the particles were connected. In a word, combined with the particle characteristics of the Yellow River silt, the solidification effect of EICP technology on the Yellow River silt is better than MICP technology. [ABSTRACT FROM AUTHOR]

Published

2023

25. 盾构渣土砖制备技术及性能研究.

Author

卞立波, 赵乙平, 张摇志, 何历超, and 胡兴波

Subjects

HUMUS, RAW materials, REFERENCE sources, TEST methods, BRICKS, CEMENT

Abstract

Copyright of Journal of Beijing University of Civil Engineering & Architecture is the property of Journal of Beijing University of Civil Engineering & Architecture Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

26. Uniaxial Creep Test Analysis on Creep Characteristics of Fully Weathered Sandy Shale.

Author

Zhang, Lianzhen, Huang, Changxin, Li, Zhipeng, Han, Zichuan, Weng, Xianjie, and Wang, Lige

Subjects

ROCK creep, SHALE, MOISTURE content of food, COMPRESSIVE strength, EMERGENCY management, RESONANT ultrasound spectroscopy, WEATHERING, HAMBURGERS

Abstract

The creep damage behavior of rocks is very important for evaluating the stability and safety of key rock engineering. Based on the Lianhua Tunnel Project in China, this paper aims to study the creep damage mechanics, the influencing factors and the creep constitutive models of sandy shale. In order to achieve these goals, a uniaxial compressive strength test and a creep test under different moisture contents and load levels were carried out. According to the test results, the creep parameters (elastic coefficients E1 and E2 and viscosity coefficients η1 and η2) of the Burgers Model were achieved, and the relationship between the creep parameters and moisture content, ω, was established accordingly (E1 = f(ω), E2 = f(ω), η1 = f(ω), η2 = f(ω)). A fully weathered sandy-shale creep constitutive model considering moisture content was finally obtained. Test results showed that creep deformation increases with any increase in load level or moisture content, and the influence of moisture content is more significant. For instance, creep deformation increased by 35% when the load increased by 50%, and creep deformation increased by 82% when the moisture content increased by 45%. In addition, the creep rate in the steady stage and the duration of the primary creep stage increased with any increase in moisture content or load level. The higher the moisture content, the greater the influence of creep deformation on the total deformation. The creep model of fully weathered sandy shale showed that the elastic coefficients (E1, E2) and the viscosity coefficients (η1, η2) are negatively correlated to moisture content; E1 is negatively correlated to load level; and E2, η1 and η2 are positively correlated to load level. Qualitative and quantitative analysis of fully weathered sandy shale can improve the existing research of creep properties and is expected to provide theoretical support for treatment of large deformation disasters in the fully weathered sandy-shale stratum. [ABSTRACT FROM AUTHOR]

Published

2023

27. 西部矿区弱胶结地层工程围岩稳定性 控制研究进展.

Author

纪洪广, 孙利辉, 宋朝阳, 张月征, 王九红, and 孟志强

Subjects

PHASE transitions, ROCK bursts, COMPRESSIVE strength, TENSILE strength, ROCK mechanics, ROCK deformation, LONGWALL mining

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

28. Influence of wet–dry cycles on uniaxial compression behavior of fissured loess.

Author

Xu, Jian, Hu, Ke, Zhou, Liyang, Li, Yanfeng, Ye, Weihang, and Wang, Songhe

Subjects

LOESS, FAILURE mode & effects analysis, ELASTIC modulus, COMPRESSIVE strength, SLOPE stability, ROCK mechanics, FREEZE-thaw cycles

Abstract

The stability of slopes of China's Loess Plateau, where fissured loess is abundant, is affected by wet–dry cycles. Uniaxial compression tests and the PCAS system were used to analyze the development of visible cracks and mechanical behavior of fissured loess over wet–dry cycles. Results show that the wet–dry cycles and the fissure angle both influence the development of cracks in fissured loess samples. The failure of fissured loess samples manifests as four main modes such as fracture failure, slip-fracture failure, slip failure, and compression-shear failure. Wet–dry cycles had a negligible effect on the failure mode in samples with fissure angles of 0°, 15°, 45°, and 60°, but were more noticeable at fissure angles of 30° and 90°, ranging from compression-shear failure to fracture failure. The initial elastic modulus and uniaxial compressive strength of fissured loess both decline after wet–dry cycles. After various wet–dry cycles, the associations between uniaxial compressive strength and fissure angle all display a double-V shaped pattern, with abrupt shifts in 45°–90° and the minimum value at a fissure angle of 60°. After wet–dry cycles, the uniaxial compressive strength of fissured loess decreases, while the amplitude of change decreases. [ABSTRACT FROM AUTHOR]

Published

2023

29. Study on Mechanical Properties and Constitutive Equation of Earth Materials under Uniaxial Compression.

Author

Yan, Jianlong, Yuan, Kang, Zhang, Fenjie, and Guo, Longlong

Subjects

STRESS-strain curves, MECHANICAL behavior of materials, MATERIALS testing, STRUCTURAL engineering, ENGINEERING design, COMPRESSIVE strength

Abstract

In this study, the uniaxial compressive mechanical properties of earth materials are tested, and the effects of four influencing factors, such as shape, size, curing age, and loading rate, on the strength, damage pattern, and stress-strain curve of the specimens are analyzed. The standard uniaxially compressed specimen size and the recommended loading rate are proposed for the earth specimens. The uniaxial compressive constitutive equations of earth materials are modified on the basis of the Illampas constitutive equation. By fitting the results of this study and typical literature tests, the applicability of the modified constitutive equation form to the uniaxial compressive test curves of soils in different regions of China based on standard sizes is verified. Finally, the formulae for calculating the parameters related to the constitutive equation of earth materials are established. In its application, only the compressive strength of 100-mm-cubic standard specimens with a curing age of 28 d needs to be measured to calculate and determine the specific values of the relevant parameters of the constitutive equation. This is a good reference value for promoting the development of computational analysis methods for earth structures and promoting the engineering design applications of earth structures. [ABSTRACT FROM AUTHOR]

Published

2023

30. The global research trend on microbially induced carbonate precipitation during 2001–2021: a bibliometric review.

Author

Omoregie, Armstrong Ighodalo, Muda, Khalida, Ojuri, Oluwapelumi Olumide, Hong, Ching Yi, Pauzi, Farhan Mohd, and Ali, Nur Shahidah Binti Aftar

Subjects

BIBLIOMETRICS, STRUCTURAL engineering, ENVIRONMENTAL engineering, STRUCTURAL engineers, COMPRESSIVE strength, CARBONATE minerals

Abstract

Microbially induced carbonate precipitation (MICP) is a remarkable method that creates sustainable cementitious binding material for use in geotechnical/structural engineering and environmental engineering. This is due to the increasing demand for alternative environmentally friendly technologies and materials that result in minimal or zero carbon footprint. In contrast to the previously published literature, through bibliometric analysis, this review paper focuses on the current prospects and future research trends of MICP technology via the Scopus database and VOSviewer analysis. The objective of the study was to determine the annual publications and citations trend, most contributing countries, the leading journals, prolific authors, productive institutions, funding sponsors, trending author keywords, and research directions of MICP. There were a total of 1058 articles published from 2001 to 2021 on MICP. The result demonstrated that the volume of publications is increasing. China, Construction and Building Materials, Satoru Kawasaki, Nanyang Technological University, and the National Natural Science Foundation of China are the leading country, journal, author, institution, and funding sponsor in terms of total publications. Through the co-occurrence analysis of the author keywords, MICP was revealed to be the most frequently used author keyword with 121 occurrences, a total link strength of 213, and 152 links to other author keywords. Furthermore, co-occurrence analysis of text data revealed that researchers are concentrating on four important research areas: precipitation, MICP, compressive strength, and biomineralization. This review can provide information to researchers that can lead to novel ideas and research collaboration or engagement on MICP technology. [ABSTRACT FROM AUTHOR]

Published

2022

31. Mechanical properties and acoustic emission analysis of desert sand concrete reinforced with steel fiber.

Author

Qu, Changwei, Qin, Yongjun, Luo, Ling, and Zhang, Liangliang

Subjects

*FIBER-reinforced concrete, *ACOUSTIC emission, *SAND, *DESERTS, *COMPRESSIVE strength, *TENSILE strength

Abstract

In this study, to reduce the consumption of natural sand and improve the utilization rate of desert sand in western China, while preparing 14 groups of samples, desert sand is used to replace natural sand by the ratio of 20%, 40%, and 60%, and steel fiber is mixed with volume fraction 0.5%, 1.0%, 1.5%, and 2.0%. The mechanical properties of the specimens, including compressive strength, splitting tensile strength, and axial compressive strength were tested. Besides, the microstructures of the samples were analyzed by SEM, XRD, and acoustic emission detection technologies to identify the damage process. The results show that the desert sand can refine the microstructure and fill the pores, and it has good comprehensive properties at a 40% substitution rate. The compression properties of specimens are not apparently improved, but the tensile strength and deformation properties are significantly improved. The steel fiber with 1.5 vol% content behaves better, and the 28d compressive strength of the optimized group reaches 58.7 MPa. As a result, the polynomial fitting degree of total AE hits and stress level receives a more incredible goodness (R2) value than 0.96. The strength characteristics of steel fiber-desert sand concrete (SFDSC) can meet the demands of C40 concrete, and this research can provide a reference for engineers using desert sand in their designs. [ABSTRACT FROM AUTHOR]

Published

2022

32. Study on Strength Development Mechanism of Organic Soil in Dianchi Lake, China.

Author

Huang, Siyang, Cao, Jing, Kong, Cheng, Gao, Yue, Song, Yunfei, Liu, Fangyi, Sun, Huafeng, Lai, Zhengcong, Zhu, Weiming, and Xu, Hanhua

Subjects

*HISTOSOLS, *SCANNING electron microscopes, *SOIL structure, *HUMIC acid, *FULVIC acids, *COMPRESSIVE strength

Abstract

The organic soil is widely distributed around Dianchi Lake in Kunming, which is rich in the humic group (HG). In order to explore the effect of HG on the strength development of organic soil, this paper adopts the method of adding humic acid (HA) reagent into the undisturbed cohesive soil (blending method) and soaking it in fulvic acid (FA) solution (steeping method) to simulate the organic soil. Then, the effect of HG on soil is analyzed by the unconfined compressive strength (UCS) and the scanning electron microscope (SEM) tests. The UCS test shows that HA can significantly reduce the UCS of the samples, and it continues to decrease with the increase of the HA reagent content. FA can substantially enhance the UCS of the samples, which continues to increase with the concentration of FA solution (decreasing the pH value). Under each HG condition, the steeping of FA can significantly increase the UCS of the sample when the content of the HA reagent is less than 10%, and the growth rate of the UCS decreases when it is greater than 10%. With the increase of steeping age, the UCS of the 5% HA samples continued to increase and gradually became stable, and when the content of the HA reagent is more than 5%, the UCS curve first increases and then decreases. The SEM test shows that adding HA reagent can significantly increase the pore size, improve the connectivity between the pores, and weaken the connection of the soil structure. The steeping of FA can reduce the pore size, weaken the connectivity between the pores, and strengthen the connection of the sample structure. [ABSTRACT FROM AUTHOR]

Published

2022

33. Effects of Hybrid PVA–Steel Fibers on the Mechanical Performance of High-Ductility Cementitious Composites.

Author

Li, Lianghui, Li, Bixiong, Wang, Zhiwen, Zhang, Zhibo, and Alselwi, Othman

Subjects

CEMENT composites, FIBROUS composites, TENSILE strength, FIBERS, POLYVINYL alcohol, SCANNING electron microscopy, COMPRESSIVE strength

Abstract

Producing high-ductility cementitious composites (HDCC) increased in parallel with concrete demand in China recently. However, the high cost of manufacturing cementitious composites (HDCC) persists. To reduce the cost of HDCC, steel fibers, polyvinyl alcohol (PVA), and river sand were used to produce HDCC concrete in the present study. A total fiber content of 2% was formed with five different proportions of PVA fiber and steel fiber. Within the scope of the experimental studies, mechanical (workability, compressive strength, tensile, and bending properties), and microstructural (scanning electron microscopy) tests were carried out to investigate the properties of the hybrid fiber-reinforced composites. The results showed that the fluidity of HDCC increased with increasing steel fiber substitution. The compressive strength of the mixture containing 0.5% steel fiber and 1.5% PVA fiber exhibited a better compressive strength of 31.3 MPa. The tensile performance of the mixture was improved due to the incorporation of steel fiber. The initial cracking strength was about 2.32 MPa, 25.4% higher than that of the reference group, and the ultimate tensile strength was 3.36–3.56 MPa. However, reducing the content of PVA fiber impacts the flexural rigidity of the matrix. [ABSTRACT FROM AUTHOR]

Published

2022

34. Quantitative Evaluation of Gypsum-Salt Caprock Sealing Capacity Based on Analytic Hierarchy Process—A Case Study from the Cambrian in the Tarim Basin, Western China.

Author

Zhao, Shan, Liu, Hua, Zhu, Yongfeng, Wang, Shen, and Yang, Xianzhang

Subjects

*GYPSUM, *ANALYTIC hierarchy process, *INTERNAL friction, *COMPRESSIVE strength

Abstract

Gypsum-salt caprock is one of the most important caprocks in petroliferous basins around the world. Its sealing capacity extremely affects hydrocarbon accumulation and distribution. However, there are numerous variables that affect caprock sealing performance, making a quantitative evaluation challenging. The analytic hierarchy process (AHP), which has the advantage of turning several influencing factors into multi-level single objectives, can be utilized in this context to quantify the weight of each element impacting caprock sealing capacity. As a result, using the Tarim Basin's Cambrian as an example, this article quantitatively assessed the gypsum-salt caprock sealing capacity using AHP. The results show that factors affecting the sealing capacity of Cambrian gypsum-salt caprock in the Tarim Basin can be summarized into three major categories and nine sub-categories, including the lithology (rock assemblage type and lithology zoning), the thickness (total thickness of thick single layer, maximum thickness of thick single layer, total thickness, and ratio of caprock to stratum), and the mechanical properties (internal friction coefficient, compressive strength, peak strength). The sealing ability evaluation index (C) was created by applying AHP to quantify a number of different characteristics. The capacity of the caprock to seal is inversely correlated with the C-value. The value of C in the plane climbs consistently from Tabei to Tazhong and subsequently to the Bachu region, indicating a steady improvement in caprock sealing ability. Additionally, the evaluation's findings are in line with how hydrocarbon accumulations are currently distributed. Furthermore, hydrocarbons are mostly distributed in subsalt and subsalt-dominated layers when C is greater than 2. On the contrary, hydrocarbons are mainly distributed in post-salt layers when C is less than 2. Furthermore, in areas affected by faults, hydrocarbons are favorably distributed in subsalt layers when C reaches 2, and fault activity is poor or strong in the early period and weak in the late period. [ABSTRACT FROM AUTHOR]

Published

2022

35. Study on Mechanical Properties and Weakening Mechanism of Acid Corrosion Lamprophyre.

Author

Guo, Jun, Mi, Xincheng, Feng, Guorui, Qi, Tingye, Bai, Jinwen, Wen, Xiaoze, Qian, Ruipeng, Zhu, Linjun, Guo, Xingchen, and Yu, Luyang

Subjects

*LAMPROPHYRES, *WATER-rock interaction, *STRESS-strain curves, *ACID solutions, *COMPRESSIVE strength, *QUARTZ, *ROCK deformation

Abstract

In order to study the weakening mechanism and mechanical behaviors of hard lamprophyre of Carboniferous Permian coal-bearing strata in China's mining area, lamprophyre samples were subjected to static rock dissolution experiments with pH values of 0, 2, and 4. The acid corrosion mechanism of lamprophyre was revealed from the weight changes of samples, characteristics of solution ion concentration, and macro-mechanical properties. The experimental results show that reaction occurred between lamprophyre and acid solution. With the increasing concentration of H+, the reaction was more intense, the degree of acid etching was higher, and the weight loss was greater. The internal damage induced by acid etching results in the slow extension of the compaction stage of stress–strain curve of uniaxial compression, and the obvious deterioration of mechanical properties of the lamprophyre. The uniaxial compressive strength of the lamprophyre in the dry state is 132 MPa, which decreased to 39 MPa under the acid etching condition, showing significant mudding characteristics. Dolomite (CaMg(CO3)2 with 19.63%) and orthoclase (KAlSi3O8 with 31.4%) in lamprophyre are the major minerals constituents involved in acidification reaction. Photomicrograph recorded from SEM studies reveals that the dissolution effect was directly related to the concentration of H+ in the solution. The dissolution effect was from the surface to the inside. The small dissolution pores became larger and continuously expanded, then finally formed a skeleton structure dominated by quartz. The content of K+, Ca2+, and Mg2+ in the solution after acid etching reaction indicates that the acidified product of orthoclase is colloidal H2SiO3, which adhered to the surface of samples during acid etching and hinders the further acidification of minerals. The dissolution of dolomite and orthoclase under acidic conditions directly leads to the damage of their structure and further promotes the water–rock interaction, which is the fundamental reason for the weakening of the mechanical properties of lamprophyre. [ABSTRACT FROM AUTHOR]

Published

2022

36. New Empirical Criterion for Evaluating Peak Shear Strength of Unmatched Discontinuity with Different Joint Wall Compressive Strengths.

Author

Tang, Zhi Cheng and Yan, Cheng Zeng

Subjects

*COMPRESSIVE strength, *ROCK slopes, *SLOPE stability, *REGRESSION analysis, *MULTIVARIATE analysis

Abstract

Discontinuities with different joint wall compressive strengths (DDJCS) are common in the Three Gorges Reservoir Area, China. Accurate estimation of the peak shear strength of DDJCS is essential for evaluating the stability of rock slope in the area. However, the coupling effects of strength difference in rock types and matching degree in rock blocks on the peak shear strength of such a discontinuity have not been well investigated. In this study, DDJCS with different matching degrees are used to conduct direct shear tests, modelled by applying horizontal dislocations between the two rock blocks along shearing direction. Experimental results illustrate that the joint peak shear strengths decrease linearly as the horizontal dislocation increases, while the ratio of peak shear strength for the unmatched DDJCS to the matched DDJCS is almost unaffected by the joint wall strength difference when the imposed lateral dislocation is equal. An empirical criterion is proposed by multivariate regression analysis to account for the above-mentioned coupling effects, which can be degraded into available criterion as the horizontal dislocation is zero. Several natural discontinuities with different joint wall compressive strengths are then collected from the Three Gorges Reservoir Area to verify the proposed criterion. Due to the low overall estimation error (about 6.20% for the unmatched rock-like discontinuities, and 12.4% for the unmatched natural discontinuities), the proposed criterion can be used to evaluate the peak shear strengths of unmatched DDJCS to some extent. Highlights: Peak shear strength of discontinuity with different joint wall compressive strengths linearly decreases as initial horizontal dislocation between the two rock blocks increases. New failure criterion is developed to evaluate the peak shear strength of unmatched discontinuity with different joint wall compressive strengths. Three factors are mainly considered by the proposed criterion: matching condition, joint wall strength difference, and three-dimensional roughness metric. [ABSTRACT FROM AUTHOR]

Published

2022

37. 冻融作用下纤维加筋固化盐渍土的 抗压性能与微观结构.

Author

柴寿喜, 张　琳, 魏　丽, and 田萌萌

Subjects

FREEZE-thaw cycles, SOIL mechanics, NUCLEAR magnetic resonance, COMPRESSIVE strength, SPRING, LIMING of soils

Abstract

Copyright of Hydrogeology & Engineering Geology / Shuiwendizhi Gongchengdizhi is the property of Hydrogeology & Engineering Geology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

38. Bioremediation of uranium enriched coal fly ash based on microbially induced calcite precipitation.

Author

Wufuer R, Duo J, Li W, Wang S, Pei L, and Yang F

Subjects

China, Halomonas metabolism, Soil Pollutants, Radioactive analysis, Soil Pollutants, Radioactive metabolism, Uranium metabolism, Coal Ash chemistry, Calcium Carbonate chemistry, Biodegradation, Environmental

Abstract

Coal fly ash (CFA) is an essential raw material in brickmaking industry worldwide. There are some coal mines with a relatively high content of uranium (U) in the Xinjiang region of China that are yet understudied. The CFA from these coal mines poses substantial environmental risks due to the concentrated uranium amount after coal burning. In this paper, we demonstrated a calcifying ureolytic bacterium Halomonas sp. SBC20 for its biocementation of U in CFA based on microbially induced calcite precipitation (MICP). Rectangle-shaped CFA bricks were made from CFA using bacterial cells, and an electric testing machine tested their compressive strength. U distribution pattern and immobility against rainfall runoff were carefully examined by a five-stage U sequential extraction method and a leaching column test. The microstructural changes in CFA bricks were characterized by FTIR and SEM-EDS methods. The results showed that the compressive strength of CFA bricks after being cultivated by bacterial cells increased considerably compared to control specimens. U mobility was significantly decreased in the exchangeable fraction, while the U content was markedly increased in the carbonate-bound fraction after biocementation. Much less U was released in the leaching column test after the treatment with bacterial cells. The FTIR and SEM-EDX methods confirmed the formation of carbonate precipitates and the incorporation of U into the calcite surfaces, obstructing the release of U into the surrounding environments. The technology provides an effective and economical treatment of U-contaminated CFA, which comes from coal mines with high uranium content in the Xinjiang region, even globally., Competing Interests: Declaration of competing interest All authors declared that they have no conflicts of interest exists to this work., (Copyright © 2024. Published by Elsevier Ltd.)

Published

2024

39. A Bibliometric Analysis of Research Progress and Trends on Fly Ash-Based Geopolymer.

Author

Tian, Quanzhi, Pan, Yinhai, Bai, Yingchu, Yao, Shuo, and Sun, Shiqiang

Subjects

*FLY ash, *SOLID waste, *BIBLIOMETRICS, *PORTLAND cement, *COMPRESSIVE strength, *BUILDING design & construction, *POLYMER-impregnated concrete

Abstract

The objective of this work is to present the research progress and applications of fly ash-based geopolymer, and summarize the future research hotpots. Since 1998, scholars have made important contributions to the study of fly ash-based geopolymer, and a large number of research studies have been published. Therefore, a bibliometric analysis for the determination of the research status, trend, and history of fly ash-based geopolymer was conducted in the present study. A total of 4352 publications on fly ash-based geopolymer were collected between 1998 and 2022, with an increasing trend year by year. China and Australia are the largest contributors to the field, and the research institutions in each country cooperate closely. In addition, the most contributing research areas are MATERIALS SCIENCE, ENGINEERING, and CONSTRUCTION & BUILDING TECHNOLOGY. The keywords including fly ash, compressive strength, and mechanical property are the most frequently appearing words. On the whole, the development of fly ash-based geopolymer could be divided into three stages including the replacement of ordinary Portland cement, the development of multifunctional materials, and the reduction of environmental impact by the conversion of solid waste. This overview could provide an important guidance for the development of fly ash-based geopolymer. [ABSTRACT FROM AUTHOR]

Published

2022

40. Prediction of Concrete Compressive Strength in Saline Soil Environments.

Author

Yang, Deqiang, Yan, Changwang, Liu, Shuguang, Jia, Zhirong, and Wang, Chunguang

Subjects

*CONCRETE durability, *COMPRESSIVE strength, *FICK'S laws of diffusion, *DETERIORATION of concrete, *ENVIRONMENTAL soil science

Abstract

Saline soil in Western China contains high concentrations of chloride ions, sulfate ions, and other corrosive ions, and the performance of concrete will substantially deteriorate from exposure to this environment. Therefore, it is of great significance to study and predict the concrete compressive strength in saline soil environments. In this paper, the effects of corrosion on concrete were analyzed from the aspects of surface damage, damage depth, and X-ray diffraction (XRD) of the corrosion products. The effects of corrosion were quantified by damage depth and corrosion depth. Then, considering the corrosion effects combined with Fick's diffusion law, a time-dependent model of concrete compressive strength and a time-dependent model of damage depth were established. The results show that the deterioration of concrete gradually developed from the surface to the interior, and that the interface of the concrete specimen was equivalent to three parts: a failure zone, a filling zone, and an undisturbed zone. The results also showed that the time-varying model of concrete compressive strength proposed by the author was fully applicable, with an error of less than five percent. The service life of concrete predicted by the damage depth was found to be about 253 months (21.1 years), and the service life predicted by the time-varying compressive strength model was about 187 months (15.6 years). Both prediction results were far less than the normal concrete service life of 50 years. In addition, the long-term compressive strength of the corroded concrete was about 90% of that of the noncorroded concrete, which did not deteriorate with the corrosion time. [ABSTRACT FROM AUTHOR]

Published

2022

41. 煤岩抗压强度和弹性模量对不同煤阶区 煤层气开发的影响.

Author

田博凡, 康永尚, 邓　泽, and 曹明亮

Subjects

COKING coal, COALBED methane, ROCK concerts, COAL gas, LIGNITE, COMPRESSIVE strength

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

42. 不同含水率膏体充填材料的单轴压缩试验研究.

Author

王永岩, 于卓群, and 崔立桩

Subjects

FILLER materials, SUSTAINABLE construction, COMPRESSIVE strength, ELASTIC modulus, MINES & mineral resources, STRESS-strain curves, PASTE

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

43. 硫酸盐-冻融共同作用下隧道衬砌支护喷射混凝土劣化性能研究.

Author

席红兵 and 李柏生

Subjects

FLY ash, FREEZE-thaw cycles, TUNNEL lining, ELASTIC modulus, SHOTCRETE, COMPRESSIVE strength

Abstract

Copyright of Tunnel Construction / Suidao Jianshe (Zhong-Yingwen Ban) is the property of Tunnel Construction Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

44. Experimental study on physical and mechanical properties and U(VI) leaching characteristics of fiber-reinforced uranium tailing geopolymer-solidified bodies.

Author

Zhang, Chao, Jiang, Fuliang, Wang, Zhe, Wu, Haonan, Tan, Biao, Hao, Yuying, Mo, Yixiang, Hu, Tao, and Wang, Hong

Subjects

*KAOLIN, *URANIUM, *LEACHING, *URANIUM ores, *URANIUM compounds, *FLY ash, *COMPRESSIVE strength, *TENSILE strength

Abstract

A uranium tailing pond in southern China is the largest in Asia. For historical reasons, uranium tailings stored in the pond have been in an acidic environment for a long time, which has caused great difficulties for decommissioning treatment of the pond. In this study, uranium tailings were taken from the beach surface of the pond as the research object. Then, 11 kinds of solidified samples of uranium tailings with different compositional ratios were prepared using water glass and sodium hydroxide, as alkali activators, and mixed with metakaolin, fly ash, and PVA or basalt fibers. The resulting solidified samples were examined in terms of microscopic characterization, compressive strength, tensile strength, resistivity, and U(VI) leaching. The results showed that, with increased fiber content, the compressive strength of samples first increased and then decreased, while the tensile strength increased continuously. The body volume resistivities first increased and then decreased and, with increased time, the leaching rate decreased continuously and finally tended to stabilize. The compressive strength and volume resistivity of samples were negatively correlated with the U(VI) leaching rate and cumulative leaching fraction. Considering the physical mechanics and U(VI) leaching resistance properties of these bodies, the best fiber proportion was concluded to be the addition of 0.2-wt% PVA fiber and 0.6-wt% basalt fiber. [ABSTRACT FROM AUTHOR]

Published

2022

45. Life Prediction Model of Wooden Structure Based on Artificial Intelligence Algorithm.

Author

Cao, Ningning

Subjects

WOODEN beams, ARTIFICIAL intelligence, PREDICTION models, AESTHETICS, STRENGTH of materials, COMPRESSIVE strength

Abstract

The ancient wooden structure in China is a precious architectural cultural heritage in history, which has high cultural and artistic value. However, due to the influence of its own material structure and the long-term preservation and maintenance process, due to long-term loads, earthquakes, fires, man-made damage, etc., ancient buildings have suffered more or less damage, which may cause sudden failure of the structure, which seriously affects the safety of the building structure. Therefore, the research on the prediction of the life of ancient wooden structures has guiding significance for sustainable development. This paper studies the life prediction of ancient buildings and introduces artificial intelligence algorithms. By comparing the old and new of the ancient building with the damage of the various structures of the ancient building, and using a variety of methods to find a more accurate method to predict the life of the ancient building, through various aspects of research and comparison, we have discovered the variation of wooden columns and beams. The coefficients are 22.97% and 22.54%, which affect the service life of wooden members. The residual strength ratios of the compressive design strength and flexural design strength of the new material and the old material are 60.42% and 26.67%, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

46. 煅烧含伊利石尾矿制备充填胶凝材料试验研究.

Author

郭 靖

Subjects

*FILLER materials, *SUSTAINABLE construction, *COMPRESSIVE strength, *SLURRY, *COST

Abstract

The large amount of tailing occupies a large amount of land, but also has a serious impact on the surrounding environment. Due to the restriction of poor plasticity and low activity, the utilization of tailings in China has many common problems,such as low added value of products and low utilization rate. Based on this,calcination ( 600 ～1000 ℃)was used to improve the reactivity of illite-containing tailings and to prepare cementing materials for cemented paste backfill. The results showed that the reactivity of illite- containing tailings increased with the increase of calcination temperature. When the mass ratio of cementitious material to tailings was 1 : 6 and the slurry concentration was 70 %, the compressive strength of backfill in 3 d and 28 d was 0.43 MPa and 2.27 MPa, respectively. On the other hand, compared with cement-based filling materials, cementitious materials prepared with illite-containing tailings for underground filling could save about 11. 87 % of filling cost. Therefore, the preparation of filling cementitious materials by illite-containing tailingsopens up a new way for bulk resource utilization of tailings, and at the same time,it is beneficial to reduce the filling cost and effectively promote the construction of green mines in China. [ABSTRACT FROM AUTHOR]

Published

2022

47. 混凝土抗压强度回弹法在建筑结构检测 与鉴定工作中的应用 .

Author

涂启华, 雷建国, 唐 平, and 吴福成

Subjects

COMPRESSIVE strength, CARBONIZATION, CONCRETE, INTUITION, ENGINEERING

Abstract

Copyright of Guangdong Architecture Civil Engineering is the property of Guangdong Architecture Civil Engineering Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

48. Experimental Application of Cement-Stabilized Pavement Base with Low-Grade Metamorphic Rock Aggregates.

Author

Yang, Qian, Liu, Yi, Zou, Haotian, Wang, Xiaoxiong, Gong, Guohuan, Cheng, Yinnan, Zhang, Liang, and Jiang, Zhengwu

Subjects

METAMORPHIC rocks, PAVEMENTS, COMPRESSIVE strength, ACCELERATED life testing, MICROSCOPY

Abstract

Low-grade metamorphic rock (LMR) is a kind of stone that is widely distributed in China. The alkali activity strictly prevents its application in conventional concrete. This paper evaluates the possibility of using LMR aggregate in cement-stabilized pavement base (CSPB). The compressive strength of CSPB prepared with LMR and limestone aggregates at various curing conditions was measured. Expansion rates were determined via accelerated simulation tests to assess the alkali reactivity of LMR, followed by microscopic analysis. Finally, the possibility of using LMR in CSPB was evaluated from the economic viewpoint. Results indicate that CSPB specimens prepared with LMR have similar compressive strength at each content of cement, regardless of curing conditions. The expansion rates of all CSPB specimens with LMR were lower than 0.1%, indicating the absence of an AAR, which was further validated by the absence of the AAR product in microscopic observations. It is inferred from the economic analysis that 70.9% lower cost can be achieved by the replacement of limestone aggregate with LMR aggregate. This demonstrates that technical, economic and environmental benefits endow LMR with wide market potential as the aggregate of CSPB. [ABSTRACT FROM AUTHOR]

Published

2022

49. Study of the Characteristics Mechanical Damage and Constitutive Model of Crushed-Rocks from High-Grade Highway in Permafrost Region.

Author

Zhang, Qinshuai, Wang, Qingzhi, Fang, Jianhong, Zhao, Xiangqing, Li, Jizhen, and Li, Shuan

Subjects

*FREEZE-thaw cycles, *DAMAGE models, *PERMAFROST, *COMPRESSIVE strength, *MICROPORES, *MICROCRACKS

Abstract

Three types of rocks are selected to conduct uniaxial compression and microscope experimental to study the influences of freeze-thaw cycles on crushed-rocks from Gonghe-Yushu high-graded highway, which is the first high-grade highway built in permafrost regions in China. Using the hypothesis of Lemaitre's strain equivalence principle and a theoretical model of crushed-rock deterioration after freeze-thaw cycles was established and verified by the experimental data. The experimental results showed that with an increase of the number of freeze-thaw cycles, the microcracks of saturated red sandstone increased, and this phenomenon is not obvious on other rocks. Moreover, different degrees of spalling and cracks appeared, with common physical parameters gradually decreasing. The uniaxial compressive strength of rock decreases exponentially with the increase of the number of freeze-thaw cycles. The mechanism of the influence of freeze-thaw cycles on the fine structure of the three different crushed-rocks were then analyzed using SEM scanning. Freeze-thaw cycles weaken the connection between rock mineral particles and increase the surface micropores. The damage model of freeze-thaw and load can well describe the damage law of crushed-rocks. [ABSTRACT FROM AUTHOR]

Published

2022

50. Effects of Gravel Size and Content on the Mechanical Properties of Conglomerate.

Author

Wang, Jianbo, Ge, Hongkui, Liu, Jiantong, Shen, Yinghao, Zhang, Zhenxin, Luo, Senlin, and Liu, Dunqing

Subjects

*GRAVEL, *CONGLOMERATE, *HYDRAULIC fracturing, *ELASTIC modulus, *COMPRESSIVE strength, *POROSITY

Abstract

The conglomerate reservoir in Mahu sag, located in the northwest margin of Junggar basin, China, is of low porosity and permeability. Hydraulic fracturing is necessary to improve oil production efficiency. However, the influence of strong reservoir heterogeneity and large difference in gravel content on mechanical properties still needs study. In this study, uniaxial compression tests were conducted on the conglomerate in which the gravel diameter ranges from 2 to 26 mm. In these tests, a large number of micro-fractures were found to be generated evenly around gravels. Additionally, we found that as the gravel content increased, the uniaxial compressive strength and elastic modulus of conglomerate decreased, and the plasticity characteristics increased. The experimental results show that the gravel content is the key factor determining the mechanical properties of the conglomerate. When gravel content is less than the critical content (~ 14.61–31.72%), at which the brittle–plastic transition of rocks exists, the macro-mechanical properties are mainly influenced by the cementing material. When gravel content is greater than the critical gravel content (~ 78.50%), failure is determined by the Hertz contact stress among the gravels. When gravel content is between (~ 14.61–31.72%) and (~ 78.50%), Orowan additional stress is the main factor determining the mechanical mechanism of rock failure. This failure is closely related to gravel content and cementation strength between the gravel and matrix. Highlights: The gravel content is the key factor of the mechanical properties of conglomerate. As the gravel content increases, the uniaxial compressive strength and elastic modulus of conglomerate decrease. The micro fracture of rock is distributed around the gravel, which is closely related to the interaction between gravel and matrix. [ABSTRACT FROM AUTHOR]

Published

2022