A new model for the prediction of secondary compression index of soft compressible soils

The total compression of soil under load is composed of three components (i.e. elastic settlement, primary consolidation settlement, and secondary compression). The consolidation component is time-dependent and its analysis is usually based on Terzaghi's theory. The chapter considers the consolidation characteristics of a soil and their experimental determination. The coefficient of consolidation can be determined by the Casagrande Logarithm-of-Time Fitting Method or the Taylor Square-Root of Time Method. The concepts of preconsolidation and overconsolidation are discussed while ways of determining the preconsolidation pressure, compression index, precompression index, and the coefficient of volume compressibility are explained. Ways to compute the settlement using coefficient of volume compressibility and e-logs methods for both normally consolidated and overconsolidated soils are provided. The chapter also explains Schmertmann (1955) graphical procedure for approximating the field compression index from the laboratory curve. It includes the derivation of Terzaghi's 1-D theory of consolidation and its solution using both analytical and graphical methods. Finally, the phenomenon and way of computing the secondary compression index are treated.

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A Calculation Method of Secondary Compression Index for Natural Sedimentary Clays Using Void Index

Soil Behavior and Geo-Micromechanics ◽

10.1061/41101(374)3 ◽

2010 ◽

Cited By ~ 1

Author(s):

Lingling Zeng ◽

Songyu Liu

Keyword(s):

Calculation Method ◽

Compression Index ◽

Secondary Compression

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Method of removing secondary compression on clay using preloading

MATEC Web of Conferences ◽

10.1051/matecconf/201819503006 ◽

2018 ◽

Vol 195 ◽

pp. 03006

Author(s):

Ega Dhianty ◽

Indrasurya B. Mochtar

Keyword(s):

Void Ratio ◽

Soft Soil ◽

Soil Improvement ◽

Compression Index ◽

Secondary Compression ◽

Initial Void Ratio ◽

Prefabricated Vertical Drain ◽

Primary Consolidation ◽

Short Time ◽

External Loads

Due to external loads, the soft soil will undergo a large compression of both primary and secondary compression. With soil improvement using prefabricated vertical drain (PVD), the time of primary compression becomes shorter so that secondary compression occurs in short time. There has been little research on how to remove secondary compression. Therefore, further investigation of behaviour and method of removing secondary compression is necessary. This research was conducted based on an experimental study of clay consolidation test with a variation of loading time in the laboratory. The results show that there is an empirical correlation among the secondary compression index (Cα’), the initial void ratio (e0), the void ratio at the end of primary consolidation (ep), and the effective consolidation stress (P’). The correlations obtained from this study are Cα’ = (0.0072e0 - 0.0067)P’ and Cα’ = (0.0077ep - 0.006)P’. The greater the effective consolidation stress is, the greater the secondary compression index will become. Therefore, in soil improvement secondary compression can be removed by giving an extra load (Δq) that causes additional compression to the primary consolidation where the magnitude equals to the expected secondary compression. Then, this Δq could be removed at the end of the primary consolidation.

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Contribution of two artificial intelligence techniques in predicting the secondary compression index of fine-grained soils

Innovative Infrastructure Solutions ◽

10.1007/s41062-020-00348-1 ◽

2020 ◽

Vol 5 (3) ◽

Author(s):

Mohammed el Amin Bourouis ◽

Abdeldjalil Zadjaoui ◽

Abdelkader Djedid

Keyword(s):

Artificial Intelligence ◽

Compression Index ◽

Artificial Intelligence Techniques ◽

Fine Grained ◽

Secondary Compression

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Geotechnical properties of a municipal water treatment sludge incorporating a coagulant

Canadian Geotechnical Journal ◽

10.1139/t07-109 ◽

2008 ◽

Vol 45 (5) ◽

pp. 715-725 ◽

Cited By ~ 18

Author(s):

Brendan C. O’Kelly

Keyword(s):

Shear Strength ◽

Water Treatment ◽

Water Content ◽

Geotechnical Properties ◽

Strength Parameter ◽

Compression Index ◽

Water Treatment Sludge ◽

Secondary Compression ◽

Municipal Water ◽

Density Values

The geotechnical properties of a municipal water treatment sludge from an upland catchment are presented. The gelatinous sludge comprised flocs of mainly quartz, manganoan calcite, and clay-sized organic solids, and incorporated an alum coagulant and an anionic polyelectrolyte. Standard Proctor compaction yielded low bulk density values of 0.95–1.10 t/m3 and dry density values of 0.12–0.36 t/m3 (water content is 160%–780%) in line with the low specific gravity of solids value of 1.86. The undrained shear strength and the water content were inversely related on a semi-log plot. The effective stress shear strength parameter values were c' = 0 and ϕ' = 39°. The consolidation properties were studied using the oedometer, consolidometer, and triaxial apparatus. The material was highly compressible with primary compression index (Cc) values of 2.5–3.7, and primary compression ratio (C*c) values of 0.20–0.28. The majority of the strain response occurred due to primary consolidation although the material had a very low permeability (coefficient of permeability values decreasing from 2 × 10−9 to 5 × 10−11 m/s for an effective vertical stress of σ'v = 3–800 kPa). Secondary compression was minor, with a mean secondary compression index (Cαe) value of 0.15, and Cαe/Cc = 0.04–0.06.

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Time-dependent behaviour of the Bearpaw Shale in oedometric loading and unloading

Canadian Geotechnical Journal ◽

10.1139/t2012-004 ◽

2012 ◽

Vol 49 (4) ◽

pp. 427-441 ◽

Cited By ~ 15

Author(s):

J. Suzanne Powell ◽

W. Andy Take ◽

Greg Siemens ◽

V.H. Remenda

Keyword(s):

Time Dependent ◽

Exact Nature ◽

Compression Index ◽

Soft Clays ◽

Consolidation Pressure ◽

Secondary Compression ◽

Clay Shales ◽

Time Dependent Behaviour ◽

The Many ◽

Dependent Behaviour

Time-dependent behaviour can have a significant influence on the compressibility characteristics of soils. However, most of the research on this topic has investigated the behaviour of soft soils. In this paper, the time-dependent behaviour of a hard clay shale (Bearpaw Shale) is investigated using both one-dimensional multi-staged loading (MSL) oedometer and constant rate of strain (CRS) oedometer consolidation tests conducted on 25.0 and 16.9 mm diameter specimens. The results show that soft clays and hard clay shales that share the same Cαe/[Formula: see text] ratio (where Cαe is the secondary compression index and [Formula: see text] is the incremental compression index) will show the same approximately 7% change in pre-consolidation pressure for an increase of one log cycle of strain rate despite the many orders of magnitude difference in pre-consolidation pressure. In the case of the Bearpaw Shale, this 7% change in pre-consolidation pressure corresponds to approximately 700 kPa. The time-dependent behaviour of the Bearpaw Shale during unloading (Cαe/[Formula: see text], where [Formula: see text] is the incremental swelling index) was observed to follow a similar ratio to that observed in compression (Cαe/[Formula: see text]). While the exact nature of the compression and swelling events that have occurred over the life of the Bearpaw Formation is not clear, the influence of secondary compression cannot be ignored for interpretation of the geological history of this deposit.

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A New Model for Calculation of the Plastic Compression Index and Porosity and Permeability of Gob Materials in Longwall Mining

Geotechnical and Geological Engineering ◽

10.1007/s10706-020-01444-w ◽

2020 ◽

Vol 38 (6) ◽

pp. 6407-6420

Author(s):

Hossein Arasteh ◽

Gholamreza Saeedi ◽

Mohammad Ali Ebrahimi Farsangi ◽

Kamran Esmaeili

Keyword(s):

Longwall Mining ◽

Compression Index ◽

New Model ◽

Plastic Compression ◽

Porosity And Permeability

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Compression of granular materials

Canadian Geotechnical Journal ◽

10.1139/t08-123 ◽

2009 ◽

Vol 46 (4) ◽

pp. 369-392 ◽

Cited By ~ 115

Author(s):

Gholamreza Mesri ◽

Barames Vardhanabhuti

Keyword(s):

Yield Stress ◽

Lateral Pressure ◽

Friction Angle ◽

Abrupt Onset ◽

Vertical Stress ◽

Compression Index ◽

Dense Sand ◽

Secondary Compression ◽

Particle Damage ◽

Coefficient Of Lateral Pressure

Compression data on over 100 sands were examined to clarify the role of particle rearrangement through interparticle slip and rotation and particle damage on primary compression, including the yield stress, secondary compression, and coefficient of lateral pressure at rest. During the increase in effective vertical stress, mechanisms such as tighter packing that promote particle locking and interparticle slip and particle damage that promote particle unlocking together determine the relationship between void ratio and effective vertical stress. Three levels of particle damage together with interparticle slip and rotation determine three types of compression behavior and a yield stress at the abrupt onset of particle fracturing and splitting. The ratio of secondary compression index to compression index is independent of whether compression results from overcoming interparticle friction through interparticle slip, from overcoming particle strength through particle damage, or both; and therefore it is a constant independent of the effective stress range. The coefficient of lateral pressure at rest of an initially dense sand starts with a value defined by the Jaky equation and the maximum friction angle and remains constant up to the abrupt onset of particle fracturing and splitting, at which point it begins to increase with an increase in effective vertical stress.

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