Effect of compactive effort on the performance of fine-grained soil–cement mixtures

This paper is mainly focusing on the stabilization of soil using sugarcane baggase ash (SBA) as a soil stabilizer. The locally available soil samples were collected and their properties were determined. Based on the laboratory test results the soil was classified as fine-grained soil. Soil stabilized blocks of dimensions 15cm x 15cm x 15cm were prepared with the following soil, cement and SBA combinations 100% soil, 80% soil + 20% cement, 80% soil +10% cement +10% SBA, 80% soil + 8% cement+ 12% SBA and 80% soil + 6% cement +14% SBA. Plain OPC cement of 43 grade and SBA from sugar factory Goa was used for the soil blocks. The blocks were moist cured for a period of 28 days. The soil stabilized blocks were then tested for their compressive strength under the universal testing machine according to BIS specifications. The effects of the SBA on the strength of the soil blocks were studied and it could be concluded that SBA can be used as a partial replacement of cement. Key words: sugarcane bagasse ash, compressive Strength, soil stabilized block, cement.

Download Full-text

Effects of A Low-Carbon Emission Additive on Mechanical Properties of Fine-grained Soil under Freeze-Thaw Cycles

Journal of Cleaner Production ◽

10.1016/j.jclepro.2021.127157 ◽

2021 ◽

pp. 127157

Author(s):

Shervin Ahmadi ◽

Hasan Ghasemzadeh ◽

Foad Changizi

Keyword(s):

Mechanical Properties ◽

Carbon Emission ◽

Low Carbon ◽

Freeze Thaw ◽

Fine Grained ◽

Fine Grained Soil ◽

Low Carbon Emission

Download Full-text

Time Delay Effects on Compactability of Soil-Cement Materials during Proctor Testing

Transportation Research Record Journal of the Transportation Research Board ◽

10.1177/0361198121998700 ◽

2021 ◽

pp. 036119812199870

Author(s):

W. Griffin Sullivan ◽

Isaac L. Howard

Keyword(s):

Time Delay ◽

Vital Role ◽

Test Method ◽

Dry Density ◽

Soil Cement ◽

Delay Effects ◽

Proctor Test ◽

Negative Effect ◽

Departments Of Transportation ◽

Cement Mixtures

The Proctor test method, as specified in AASHTO T134 and ASTM D558, continues to play a vital role in design and construction quality control for soil-cement materials. However, neither test method establishes a methodology or standardized protocols to characterize the effects of time delay between cement addition and compaction, also known as compaction delay. Compaction delay has been well documented to have a notably negative effect on compactability, compressive strength, and overall performance of soil-cement materials, but specification tools to address this behavior are not prevalent. This paper aims to demonstrate the extent of compaction delay effects on several soil-cement mixtures used in Mississippi and to present recommended new test method protocols for AASHTO T134 to characterize compaction delay effects. Data presented showed that not all soil-cement mixtures are sensitive to compaction delay, but some mixtures can be very sensitive and lead to a meaningful decrease in specimen dry density. Recommended test method protocols were presented for AASHTO T134 and commentary was presented to provide state Departments of Transportation and other specifying agencies a few examples of how the new compaction delay protocols could be implemented.

Download Full-text

Modeling the Compaction Characteristics of Fine-Grained Soils Blended with Tire-Derived Aggregates

Sustainability ◽

10.3390/su13147737 ◽

2021 ◽

Vol 13 (14) ◽

pp. 7737

Author(s):

Amin Soltani ◽

Mahdieh Azimi ◽

Brendan C. O’Kelly

Keyword(s):

Energy Levels ◽

Model Development ◽

Dry Mass ◽

Unit Weight ◽

Power Functions ◽

Compaction Characteristics ◽

Practical Applications ◽

Fine Grained ◽

Practical Procedure ◽

Fine Grained Soil

This study aims at modeling the compaction characteristics of fine-grained soils blended with sand-sized (0.075–4.75 mm) recycled tire-derived aggregates (TDAs). Model development and calibration were performed using a large and diverse database of 100 soil–TDA compaction tests (with the TDA-to-soil dry mass ratio ≤ 30%) assembled from the literature. Following a comprehensive statistical analysis, it is demonstrated that the optimum moisture content (OMC) and maximum dry unit weight (MDUW) for soil–TDA blends (across different soil types, TDA particle sizes and compaction energy levels) can be expressed as universal power functions of the OMC and MDUW of the unamended soil, along with the soil to soil–TDA specific gravity ratio. Employing the Bland–Altman analysis, the 95% upper and lower (water content) agreement limits between the predicted and measured OMC values were, respectively, obtained as +1.09% and −1.23%, both of which can be considered negligible for practical applications. For the MDUW predictions, these limits were calculated as +0.67 and −0.71 kN/m3, which (like the OMC) can be deemed acceptable for prediction purposes. Having established the OMC and MDUW of the unamended fine-grained soil, the empirical models proposed in this study offer a practical procedure towards predicting the compaction characteristics of the soil–TDA blends without the hurdles of performing separate laboratory compaction tests, and thus can be employed in practice for preliminary design assessments and/or soil–TDA optimization studies.

Download Full-text

Assessment for Thermal Conductivity of Frozen Soil Based on Nonlinear Regression and Support Vector Regression Methods

Advances in Civil Engineering ◽

10.1155/2020/8898126 ◽

2020 ◽

Vol 2020 ◽

pp. 1-12

Author(s):

Fu-Qing Cui ◽

Wei Zhang ◽

Zhi-Yun Liu ◽

Wei Wang ◽

Jian-bing Chen ◽

...

Keyword(s):

Thermal Conductivity ◽

Support Vector Regression ◽

Nonlinear Regression ◽

Prediction Accuracy ◽

Prediction Models ◽

Frozen Soil ◽

Support Vector ◽

Soil Thermal Conductivity ◽

Fine Grained ◽

Fine Grained Soil

The comprehensive understanding of the variation law of soil thermal conductivity is the prerequisite of design and construction of engineering applications in permafrost regions. Compared with the unfrozen soil, the specimen preparation and experimental procedures of frozen soil thermal conductivity testing are more complex and challengeable. In this work, considering for essentially multiphase and porous structural characteristic information reflection of unfrozen soil thermal conductivity, prediction models of frozen soil thermal conductivity using nonlinear regression and Support Vector Regression (SVR) methods have been developed. Thermal conductivity of multiple types of soil samples which are sampled from the Qinghai-Tibet Engineering Corridor (QTEC) are tested by the transient plane source (TPS) method. Correlations of thermal conductivity between unfrozen and frozen soil has been analyzed and recognized. Based on the measurement data of unfrozen soil thermal conductivity, the prediction models of frozen soil thermal conductivity for 7 typical soils in the QTEC are proposed. To further facilitate engineering applications, the prediction models of two soil categories (coarse and fine-grained soil) have also been proposed. The results demonstrate that, compared with nonideal prediction accuracy of using water content and dry density as the fitting parameter, the ternary fitting model has a higher thermal conductivity prediction accuracy for 7 types of frozen soils (more than 98% of the soil specimens’ relative error are within 20%). The SVR model can further improve the frozen soil thermal conductivity prediction accuracy and more than 98% of the soil specimens’ relative error are within 15%. For coarse and fine-grained soil categories, the above two models still have reliable prediction accuracy and determine coefficient (R2) ranges from 0.8 to 0.91, which validates the applicability for small sample soils. This study provides feasible prediction models for frozen soil thermal conductivity and guidelines of the thermal design and freeze-thaw damage prevention for engineering structures in cold regions.

Download Full-text

Physical and Mechanical Properties of Fine-Grained Soil in the Zhejiang-Fujian Coastal Area, China

Marine Georesources and Geotechnology ◽

10.1080/1064119x.2011.558373 ◽

2011 ◽

Vol 29 (4) ◽

pp. 333-345 ◽

Cited By ~ 5

Author(s):

Yuan-Qin Xu ◽

Pei-Ying Li ◽

Ping Li ◽

Le-Jun Liu ◽

Cheng-Xiao Cao ◽

...

Keyword(s):

Mechanical Properties ◽

Coastal Area ◽

Physical And Mechanical Properties ◽

Fine Grained ◽

Fine Grained Soil

Download Full-text

Centrifuge testing of soil–structure interaction effects on cyclic failure potential of fine-grained soil

Earthquake Spectra ◽

10.1177/8755293020981978 ◽

2021 ◽

pp. 875529302098197

Author(s):

Jason M Buenker ◽

Scott J Brandenberg ◽

Jonathan P Stewart

Keyword(s):

Soil Structure ◽

Interaction Effects ◽

Soil Structure Interaction ◽

Centrifuge Testing ◽

Geotechnical Centrifuge ◽

Structure Interaction ◽

Fine Grained ◽

Stiffness Properties ◽

Fine Grained Soil ◽

Strip Footings

We describe two experiments performed on a 9-m-radius geotechnical centrifuge to evaluate dynamic soil–structure interaction effects on the cyclic failure potential of fine-grained soil. Each experiment incorporated three different structures with a range of mass and stiffness properties. Structures were founded on strip footings embedded in a thin layer of sand overlying lightly overconsolidated low-plasticity fine-grained soil. Shaking was applied to the base of the model container, consisting of scaled versions of recorded earthquake ground motions, sweep motions, and step waves. Data recorded during testing were processed and published on the platform DesignSafe. We describe the model configuration, sensor information, shaking events, and data processing procedures and present selected processed data to illustrate key model responses and to provide a benchmark for data use.

Download Full-text