Abstract
Consolidation rate has significant influence on the settlement of structures founded on soft fine-grained soil. This paper presents the results of a series of small-scale and large-scale Rowe cell consolidation tests with pore water pressure measurements to investigate the factors affecting the consolidation process. Permeability and creep/resistance structure factors were considered as the governing factors. Intact and reconstituted marine clay from the Polish Carpathian Foredeep basin as well as clay–sand mixtures was examined in the present study. The fundamental relationship correlating consolidation degrees based on compression and pore water pressure was assessed to indicate the nonlinear soil behaviour. It was observed that the instantaneous consolidation parameters vary as the process progresses. The instantaneous coefficient of consolidation first drastically increases or decreases with increase in the degree of consolidation and stabilises in the middle stage of the consolidation; it then decreases significantly due to viscoplastic effects occurring in the soil structure. Based on the characteristics of the relationship between coefficient of consolidation and degree of dissipation at the base, the consolidation range that complies with theoretical assumptions was established. Furthermore, the influence of coarser fraction in clay–sand mixtures in controlling the consolidation rates is discussed.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
1 Introduction
Compression, as far as is usually recorded in consolidation tests, measurement of pore water pressure is still not a routine practice. In engineering literature, there are fewer methods for analysing pore water pressure behaviour during consolidation than for observed deformation. Shortly after the formulation of the Classic Theory of Consolidation [62], Taylor [60] stated that conventional testing methods (based on strains) do not give sufficient data for a true interpretation of consolidation behaviour and for reliable comparison between test results and theory. To overcome the unsatisfactory results, much more attention was paid to pore water pressure measurements during consolidation testing. In the second half of the twentieth century, research was focused around the dominant influence of the pore water pressure measuring system on early stages of consolidation and the duration of the previous load increment [17, 43, 70]. In the studies by these above-mentioned authors, results of consolidation tests indicated the occurrence of delay in pore water pressure mobilisation, e.g. time lags in pore water measurements, characterised by an increase in the pore water pressure, until its stabilised maximum value was reached.
Perloff et al. [50] presented an analytical solution describing the effect of flexibility of the pore water pressure measuring system on the distribution of pore water pressure in a specimen during consolidation. Christie [9] clarified the effect of flexibility of the pore water pressure measuring system using the theoretical solutions of an extension of Terzaghi’s theory. There have also been some reports on contradiction in relation to the classical assumptions of instantaneous and complete transmission of an external load to the liquid phase of the sample [3, 21, 32, 56, 79, 80].
In other respects, research on laboratory measured pore water pressure highlighted that the derived vertical coefficient of consolidation, cv, differs significantly compared to that determined from compression data [14, 44, 48, 49, 53, 66]. Robinson [51] proposed a linear relationship between pore water pressure and compression for determining cv. This method is based on the uniqueness of excess pore water pressure and compression using the linearity concept of consolidation characteristics. A subsequent study conducted by Robinson [52] revealed that the secondary compression actually starts during the dissipation of excess pore water pressure, and its beginning strongly depends on the load increment ratio, LIR. Thus, the observed settlement is due to a combination of pore water pressure dissipation during primary consolidation and secondary compression. However, the evolution of compression during the dissipation process has only been investigated marginally and has not been sufficiently documented. The main objective of this study was to investigate the conditions of compression development during pore water pressure dissipation. Therefore, the uniqueness of theoretical relationship correlating the degrees of consolidation was evaluated and discussed. In addition, attention was paid to the methodological aspects in determination of cv based on compression and pore water pressure. The key issue for predicting the rate of settlement is the reliable determination of cv. Considering that Terzaghi’s theory of consolidation is based on the principle of time scaling of the consolidation process, according to which the settlement time is proportional to the length of the drainage path, the conditions of pore water pressure dissipation become crucial. The determination of cv based on pore water pressure data relates this parameter to the filtration aspect of the process and permeability of the medium. One definite advantage of this approach is that it facilitates the comparison of laboratory dissipation data with the piezocone dissipation test results. To the author’s knowledge, there is no full matching method for the calculation of cv based on pore water pressure. Thus, a novel method is proposed in this study in which a gradient-based algorithm for finding optimal value of cv is incorporated. The principle of the presented method is similar to the piezocone dissipation test method [2, 7, 10, 22, 31, 55, 58] and relates cv to the permeability of the soil rather than to its compressibility. Furthermore, the concept of instantaneous cv was used to illustrate the nonlinear consolidation behaviour and to study the difference in consolidation time at the end of primary consolidation determined by using two types of laboratory data.
In the experiments presented in this paper, compression and dissipation rates during one-dimensional consolidation were examined. For this purpose, tests on intact, reconstituted marine clay and artificially prepared mixtures of clay and fine sand were conducted to better understand the soil behaviour. Furthermore, special attention was paid to the fundamental factors that govern the consolidation process. In this way, two types of consolidation curves were numerically modelled using a gradient-based algorithm to find the optimal value of cv. All the simulations in this study were carried out on multiple-stage loading (MSL) Rowe cell tests.
2 Consolidation rates during one-dimensional loading
The rational theoretical description of the consolidation process refers to the idealised, two-phase mineral skeleton-water system, whose laboratory equivalent is a soil slurry devoid of structural bonds. Ensuring a fully saturated state of the tested material and restricted control of the conditions of the experiment allowed us to carefully investigate the evolution of compression (time-dependent volumetric strain defined as (e0 − ei)/(1 + e0) × 100%) along the excess pore water pressure dissipation. Two simultaneous observations of this phenomenon can be very useful in the prediction of real material behaviour undergoing consolidation due to loading. Permeability controls the rate at which water is expelled out of the soil and compressibility controls the evolution of excess pore water pressures [57]. Then, a combination of permeability and compressibility can be used to establish the rate of strain at any time and the duration of consolidation. Based on a simple case of Terzaghi theory, three assumptions about consolidation behaviour of fine-grained soil can be made:
-
(i)
There is a uniqueness of excess pore water pressure and the course of compression,
-
(ii)
there exists a convergence between theoretical and experimental consolidation curves, and
-
(iii)
the constancy of cv is valid throughout entire dissipation process.
2.1 Two definitions of degree of consolidation
For orderliness, the partial differential equation that governs the consolidation and pore water pressure, the dissipation process is expressed as follows:
A solution of Eq. (1) for a set of adequate boundary conditions describes how the excess pore water pressure, u, dissipates with time, t, and location, z. To assess assumption (i), it is convenient to qualitatively describe the relationship between two otherwise defined global, non-dimensional measures of the process [60]. In the study presented herein, deformation of the soil and pore water pressure was simultaneously measured and experimental data were converted into the degree of consolidation, U, which is directly proportional to the percentage consolidation [61]. Thus, two definitions of this parameter can be derived. The first is defined by axial strain or compression, and it is referred to as the average degree of consolidation, Uε; the second is defined by an excess pore water pressure, and it is referred to as the degree of dissipation at the base of the sample, Uub. At a given moment, the experimental degree of consolidation calculated on the basis of strain can be expressed as:
The relationship between the degree of consolidation and the dimensionless time factor, Tv, can be derived using the Terzaghi theory as follows:
On the other hand, when excess pore pressure is measured at the base of soil sample under consolidation with drainage only on the top of the sample, we can use following expression:
It is to be noted that the measurement of ui at the base of the sample pertains to the threshold distribution of the pore water pressure.
The theoretical degree of consolidation in this case can be derived as:
Equations (3) and (5) represent both traditional and exact solutions for Terzaghi’s consolidation theory, which was proved by Lovisa using a method where the mass flux per unit area at each drainage boundary was determined [38]. The consolidation process can be considered as actually completed when the excess pore water pressure is dissipated as a result of the increase in load. However, for the nonlinear dependence between changes in the pore water pressure and void ratio (strain) [11], the degree of dissipation at any time t calculated on the basis of the pore pressures is not equal to the average degree of consolidation, which can be expressed as follows:
2.2 Relationship between Uε and Uub
Figure 1 presents the theoretical unique relationships between degrees of consolidation Uε, Uub and the non-dimensional time factor, Tv, and the relationship correlating those degrees. As illustrated in this figure, a linear relationship exists between Uε and Uub, when Uub > 35% (unique linear increase in compression with the progress of pore water pressure dissipation).
The rate of this linear relationship specified by ΔUε/ΔUub was established as 0.64. This feature can be used to assess the experimental results theoretically. For a given fine-grained soil, any observed discrepancy from a theoretical line can be used as a diagnostic tool to highlight nonlinear soil behaviour. Some Rowe cell consolidation test results on various worldwide soft soils with different mineralogy and physical properties such as Atterberg limits were selected for the first sight appraisal. Table 1 summarises basic physical properties of the chosen soils. Figure 2 depicts a plasticity chart for classification purposes as per European Soil Classification System (ESCS) [30]. Most of these soils were found to plot above an A-line, defined by Ip = 0.73 (wL − 20) in the chart and represent a wide spectrum of plasticity. From Fig. 3, it is evident that the experimental Uε − Uub relationships for various soils are not unique and vary as consolidation progresses for particular soil. The vast majority of experimental curves are located below the theoretical line. Zeng et al. [80] related the location of an experimental Uε − Uub curve to the amount of consolidation degree happening within the period from the end of primary consolidation based on the deformation–time curve (EOPε) to the end of primary consolidation determined by the excess pore water pressure observations (EOPu). For this purpose, the degree of consolidation due to the excess pore pressure dissipation at EOPu was used. It is to be noted that Zeng el al. [80] obtained EOPε by the Casagrande procedure [5]. The authors concluded that the experimental Uε − Uub curve with a larger amount of consolidation degree difference between EOPε and EOPu is located above the theoretical line. For Huaian clay, Lianyungang clay and Nanjing clay, a decreasing trend in the amount of consolidation degree with the decrease in liquid limit was also observed. The accuracy of estimation of EOP strain from the consolidation curve will be discussed further together with the analysis of compression development during excess pore water pressure dissipation and instantaneous consolidation parameters.
3 Experimental methods
3.1 Experimental setup
In the study presented herein, to investigate compression development during excess pore water pressure dissipation, two hydraulic consolidation set-ups of different sizes were used to carry out multiple-stage loading tests (MSL). Multiple-stage loading with reloading at EOP consolidation tests (MSL)p and 10 days long-term multiple-stage loading consolidation tests (MSL)10 were used for the investigation (Table 2). The research schedule included (MSL)p and (MSL)10 experiments in a small-scale Rowe cell and large-scale Rowe cell (internal diameter of 75 mm and 151.4 mm, respectively). The sketch of the Rowe cell apparatus is shown in Fig. 4. Possible disadvantages of the Rowe cell were highlighted by Khan and Garga [28] and Blewett et al. [4]. (MSL)p tests were performed on low hydraulic conductivity reconstituted and intact clay, which enables the careful registration of effects related to filtration and creep. Conducting tests on reconstituted samples treated as debonded material was intended to eliminate the influence of soil structure. To study the effect of grain size composition and permeability on the consolidation behaviour, the (MSL)10 tests in large-scale Rowe cell were performed on artificially prepared samples consisting of mixtures of fine and coarse fractions in various proportions.
3.2 Testing procedure
Appropriate testing procedure is required to gather high-quality data from MSL test in the Rowe cell. The way to achieve this is through the following three test stages: (i) saturation (B-check), (ii) pore pressure mobilisation and (iii) consolidation. For experiments in small-scale Rowe cell, saturation of soil sample with water was led in stages with subsequent diaphragm loads (cell pressures) of 100,150, 200, 250 and 300 kPa, at respective back pressures of 90, 140, 190, 240 and 290 kPa. The values explained above were chosen by reference to the loading scheme. The B-value for each step was calculated as the ratio of the increase in the excess pore water pressure to the applied stress increment according to procedure given by Head [20]. For all tests, the B-value was between 0.97 and 0.99. The tests with a uniform stress distribution and single-sided drainage (PTIB) were conducted, and 300 kPa back pressure was maintained during testing. Diaphragm loads of 600, 900 and 1200 kPa were used for the tests, giving effective pressures of 300 kPa, 600 kPa and 900 kPa, so that load increment ratios (LIR) of 1.0, 0.5 and 0.33, respectively, were achieved. Figure 5 shows typical excess pore water pressure normalised by the load increment, CIL = Δu/Δσ′ for a low hydraulic conductivity reconstituted marine clay. The high values of CIL parameters and practically only a few seconds of build-up time indicated fully saturated state of soil and immediate load transfer to the samples.
The loads were doubled at each increment (LIR = 1.0) for the large-scale Rowe cell experiments, and the values of effective pressure ranges were 25–50 kPa, 50–100 kPa, 100–200 kPa and 200–400 kPa. The B-check procedure was the same as above, with appropriate subsequent diaphragm and back pressures to ensure sufficient B-value. A permeability test was carried out after the completion of consolidation at each load step. The samples were subjected to vertical filtration in the bottom-up direction. The measurement of hydraulic conductivity (discharge method under constant pressure) was carried out by inducing a flow through the soil specimen by adjusting the influent pressure to 20 kPa for a load of 50 kPa. However, after the end of consolidation at loads greater than 50 kPa, the influent pressure was raised to 50 kPa. The amount of expelled water was also measured with the help of a measuring cup. Such a procedure is preferred to compare the values of discharge readings from the cup with the values of discharge measured in the Rowe cell.
3.3 Preparation of samples
The basic soil material used in the present study was a Middle Miocene marine deposit of Krakowiec clay, collected from a site near Tarnobrzeg in southeastern Poland, on the east bank of the river Vistula (northeastern part of the Carpathian Foredeep). The selected clay generally consists of illite, quartz, montmorillonite and calcite, with illite as the main clay mineral. The sensitivity, St, of the Krakowiec clay from the investigated depth of 6 m is 4.57 [46]. In this study, the behaviour of reconstituted and intact kaolinite clay as well as a mixture of clay with coarse fractions was the focus of interest. Based on the results shown in Table 1 and Fig. 2, the soil was found to plot above an A-line in the plasticity chart and was classified as high plasticity CLAY (ClI) as per ESCS in accordance with the European Standard EN ISO 14688-2 [15].
The tests in the small-scale Rowe cell were carried out on the sediment obtained from the clay slurry. To obtain the clay fraction, kaolinite slumps were crushed and rubbed with distilled water by a mesh diameter of 0.0063 mm, and the thicker fractions remaining on the sieve were collected for the determination of particle-size distribution. The clay slurry was left for 2 days for sedimentation, and then, the clarified water was removed from the top surface, and the material was dried at 105 °C. The homogenous samples were obtained by mixing a certain quantity of water with the powder to prepare a slurry at a moisture content corresponding to the liquid limit.
To evaluate the effect of particle-size distribution on the value of determined consolidation parameters, the tests were carried out on samples consisting of clay–sand mixtures in various proportions, thus obtaining mixtures of a different permeability. The modelling of the sample grain composition consisted of two stages: pulping the proper weight of the dried clay in the mortar and preparing fractions of specific weights (0.1 mm < φ < 0.5 mm). The reconstituted samples were prepared in the laboratory as three batches of different size-ratios between fine and coarse particles, that is, χ values of 0.25, 0.50 and 0.75. Figure 6 shows the effect of particle-size distribution on permeability of the testing materials. The first sample (RM1) consisted of 25% fines and 75% mixture of coarse grains (χ = 0.25). In the second sample (RM2), the fines content constituted 50% (χ = 0.50). In the third sample (RM3), the proportions of the mixture components were reversed: 75% fines and 25% mixture of the remaining fractions (χ = 0.75). The weights obtained in different proportions were mixed with an amount of distilled water to create a homogeneous slurry, which was poured into the consolidation cell. Two different sizes of samples were used in this study. The thin sample of 30 mm height and 75 mm diameter was tested in a small-scale Rowe cell. The thick sample of 40 mm height and 151.4 mm diameter was tested in a large-scale Rowe cell.
4 Dissipation pore water pressure induced compression
Small-scale Rowe cell experiments on both reconstituted and intact Krakowiec clay were conducted according to the restricted EOP criterion. Mesri et al. [42] observed that during the secondary consolidation phase (practically constant effective vertical stress), there is a small amount of excess pore water pressure left that tends to be dissipated from pore space due to the act with creep deformation. The choice of an appropriate EOP criterion based on the pore water pressure was suggested by Aboshi [1], Choi [8], Mesri and Choi [42], Feng [16], Kabbaj et al. [27], Kim and Leroueil [29], Mesri et al. [42] and Watabe et al. [68]. In this work, the EOP criterion was established based on initial and final excess pore water pressure, uf = 1% u0. Hence, the duration of each load increment depends on the dissipation of the excess pore water pressure. The achieved time for the completion of dissipation does not exceed four days for all tests provided in the small-scale Rowe cell.
The consolidation process is traditionally divided into two successive phases: a primary consolidation phase and a secondary consolidation phase. During the primary consolidation phase, soil compression is controlled by the dissipation of excess pore water pressure and time-dependent (creep) deformations. It should be noted that in most fine-grained soils, the dissipation process is delayed by the viscous-plastic effects [18, 69]. The excess pore water pressure is dissipated at the end of primary consolidation (EOP), and the initial total applied stress is fully effective. Thereafter, the soil continues to deform, but at a rate controlled by soil viscosity. This is referred to as the secondary consolidation phase, and a point marking the transition between the two phases is the EOP state. However, one could assume that creep may occur during the primary consolidation phase along with the dissipation of excess pore pressure and the total deformation of consolidation may show dependency on the duration of consolidation, and hence the thickness of the clay layer or the length of the drainage path [1, 3]. In this work, it is assumed that creep is a process in which the deformation of soil will occur as a function of time and that the creep rate is controlled by viscous resistance [19]. Joseph [25] studied the viscous and secondary consolidation phenomena to understand their physical mechanisms using the Dynamical Systems Theory [26]. Suggestion was made that viscous behaviour occurs both during and after primary consolidation in accordance with Creep Hypothesis B and is due to the strain rate dependence of the coefficients of friction at interparticle contacts. This view is referred to as the isotache theory in which the strain at EOP consolidation increases with the thickness of the clay and leads to unique secondary compression behaviour [12, 13, 18, 19, 35, 37, 72, 81, 82]. According to Joseph [25], secondary compression is the continued deformation (after completion of dissipation of the excess pore water pressure) of the soil structure after consolidation due to the small numbers of particles moving at random shear strains, in a Poisson process, to the new final positions. Based on Hypothesis B, many different elastic viscoplastic (EVP) constitutive models have been used to calculate consolidation settlements of soft soil ground [71, 73, 76,77,78, 83]. In contrast, there is also evidence which suggests that similar strain levels at EOP along any stage of consolidation can occur independently of the thickness of consolidated layer and duration of primary consolidation [36, 40]. This independence is often referred to as Creep Hypothesis A, which implies the same mobilised preconsolidation pressure in the field as the preconsolidation pressure determined from laboratory tests on thin samples.
4.1 Predominant factors controlling the rate of volume change
There are two different factors that drive the consolidation process. One can be associated with permeability and is called the hydrodynamic factor. The second can be established on the basis of viscous/time-dependent behaviour and is referred to simply as the resistance of soil structure/creep factor [11]. Figure 7 presents the typical consolidation rates during one-dimensional loading resulting from (MSL)p tests on reconstituted Krakowiec clay (sample IK2 and IK3). The strain and pore water pressure data were converted in this way into the degree of consolidation and then compared. It is seen that the superimposed Uε − t and Uub − t curves indicate stress-dependent soil behaviour and clearly show the dominance of one factor over another when single load increment is considered. Given that Terzaghi’s theory assumes uncoupled consolidation equations, excess pore water pressure and strain are determined separately (no hydro-mechanical coupling). Separate analysis of compression data collected from three successive load increments reveals an increasing trend in the delay of consolidation rate together with an increase in the applied effective vertical stress. In contrast to the strains developed in the samples, the consolidation behaviour determined by pore water pressure records is the opposite. Consolidation rates increase with an increase in the applied effective stress, which show a faster rate of pore water pressure dissipation with increasing load. As can be seen in Fig. 7, the gap between Uε − t and Uub − t curves decreases with an increasing stress. Similar characteristics of the compression and dissipation rates at high effective stresses arise from pore structural changes and possible breakdown of the solid particles. The pore structural changes are mainly influenced by the movement and rearrangement of soil aggregates, shearing of the soil particles and the resulting changes in the soil hydraulic properties. However, of much more interest is the comparison of the two rates in a single load increment.
Consolidation rate is commonly described by the coefficient of consolidation, cv, which depends on soil mineralogy, loading time, load application method, overburden load history, drainage conditions and thickness of the consolidated layer [36]. It is well documented that laboratory determination of this parameter strongly depends on the method used for its computation [33, 39]. Particular methods use a different matching of a single experimental point to the related consolidation progress for deriving cv [5, 60, 63,64,65]. The main differences between these methods are based on the distinct graphical procedures used to find the primary consolidation range, e.g. 0% and 100% percentage of consolidation. Moreover, the application of some methods strongly depends on the shape of consolidation curves. Essentially, for soils that do not exhibit theoretical S-shaped settlement–time curves (type I according [33, 67]), it is unreasonable to use graphical methods in which the linear part of secondary consolidation should be distinguished from the curve to determine the consolidation parameters [39, 44, 45]. This inconvenience is associated with the Casagrande method (CA). When recorded data from the consolidation test produce ‘flat-shaped’ curve or when the curves exhibit no inflection point, it is impossible to determine the consolidation parameters by most of these methods. To overcome the drawbacks and limitations of existing graphical procedures, the optimisation approach was proposed for the determination of cv and simulation of all tests.
4.2 Optimisation MSL consolidation tests
In mathematical optimisation, the gradient (GR) method is a first-order iterative algorithm for finding the minimum or maximum of a function, which plays an important role in solving many inverse problems [23, 24, 34, 74, 75, 79]. Using the inverse analysis, a given model is calibrated by iteratively changing input values until the simulated output values match the observed data. An inverse problem in consolidation is defined as the process of calculating from a set of observations the accurate value of cv that produced them and could be resolved with the help of gradient-based algorithm. Given that this is a mono-objective problem, cv with the lowest error was selected and was considered as the optimal value for experimental results. Such approaches have been adopted and validated for various natural and artificial geomaterials by Dobak and Gaszyński [14], Olek and Pilecka [47] and Olek [45]. To carry out the GR method at a suitable level of accuracy, a function that could evaluate the error between the experimental and theoretical solutions and then minimise this function should be defined. In the work described herein, convergence with the smallest possible discrepancy was assessed by the scalar error function expressed as follows:
To reduce the influence of factors which affect the error function such as the shape of the experimental consolidation curve, a number of measurement points and the scale effects on the fitness between the experimental and the simulated results, weighted to each calculation point, were adopted as follows:
The proposed approach for determining the cv is done through the combination of the complete range of theoretical and experimental consolidation courses. The determination of cv by an existing methods is attributed to the use of specific points on consolidation curve, while in the GR method, a representative average consolidation rate is considered. Other advantages of the optimisation approach have been pointed out by Olek [48]. After using the compression and pore water pressure data to determine the values of cv, a qualitative assessment regarding which governing factor of consolidation is dominant can be done with the use of the η parameter. This estimate can be called the factor of dominance, η. Therefore:
If η = 0, there is full agreement between the excess pore water pressure dissipation and the course of strain, and therefore, the consolidation process is governed by the two factors equally. However, if η > 0, there is a delay in the rate of pore water pressure dissipation with respect to soil compression rate. In this case, creep is the dominant factor. When η < 0, the hydrodynamic factor drives the consolidation process and causes a rate of dissipation faster than the compression rate. Thus, the study of the changes in the η gives a description of permeability evolution with the consolidation progress and the subsequent load increments. Moreover, it is useful in prediction of the consolidation governing factors contribution in the formation of the settlement.
4.2.1 Multiple-stage loading with reloading at EOP consolidation tests (MSL)p
Figure 8 illustrates selected successive target values for cv to be optimised together with corresponding objective errors for (MSL)p tests. In addition, the η parameter was marked for each set of experimental data from a single load increment. As shown in the figure, the η parameter takes positive, negative or close to zero values that depends on the susceptibility of soil body to the viscous/time-dependent deformation. Despite the change in soil porosity (decrease) during loading, the pore pressure dissipation rate increased with increasing stress, and the η parameter was used to explain this observation. In general, the η parameter decreases with increasing stress for all three tests. Positive values of the η parameter, usually at the first two load increments, indicate a significant delay in pore pressure dissipation due to creep. This behaviour can be associated with heterogeneous distribution of pores in samples and difficulties in water flow through the medium. As the stress increases, privileged water migration paths in the soil structure are formed through which water is able to flow. Hence, η parameter is a good indicator of the changes in permeability during the consolidation process.
Figure 9 presents an example of simulated results of two successive load increments for the IK2 sample. Apparently, the general consolidation behaviour of the tested reconstituted soil, under two successive load increments, indicates mixed conditions in terms of domination of the governing factor during the process. These results confirm previous observations made by Robinson [51] and Olek [48] which revealed that both factors have come to be recognised as playing interacting roles in consolidation. However, consolidation behaviour of soil is more complex and cannot be directly illustrated only by the single η parameter. This is evident mainly for large-scale Rowe cell experiments, where there are much longer drainage paths and a much greater impact of nonlinear compressibility of soil affecting the consolidation behaviour.
4.2.2 Long-term multiple-stage loading consolidation tests (MSL)10
The comparisons between simulations and experimental data for pore pressure response during long-term consolidation tests in large-scale Rowe cell (MSL)10 on mixtures with different size-ratios between fine and coarse particles, χ, are presented in Fig. 10. Following the optimisation approach described in this section, cv values related to the rate of dissipation were established. At first sight, the corresponding values of the objective error, which lie between 0.031% and 0.2076%, indicate a good agreement between the experiments and simulations. As the tests in large-scale Rowe cell were conducted up to ten days, a large amount of secondary consolidation governed by creep was obtained. Therefore, the simulated curve relates to idealised conditions of the Terzaghi model and can be an indicator of the impact of viscous-plastic mechanisms, delaying the dissipation of pore water pressure at later stages of consolidation. Hence, the simulation produces reliable results for early and/or middle consolidation stages when the dissipation process is less affected by viscous/time dependency. The observed delay in dissipation rate can be discussed with the help of functional relationship between instantaneous cv and degree of dissipation at the base, Uub. This will be further investigated in the next section.
4.3 Compression development during excess pore water pressure dissipation
To recognise the development of compression during excess pore water pressure dissipation, the experimental relationships between Uε and Uub were studied. The linear portion of Uε − Uub curve − that is, the primary consolidation range—was characterised by instantaneous values of cv, which remained constant, while U and Tv varied or increased linearly with compression and time. Instantaneous values of cv were calculated for each experimental point on consolidation curve according to the procedure developed by Olek [48]. This procedure facilitates the verification of assumption (iii) and the assessment of the optimal value of cv determined by the GR method.
4.3.1 Experiments in small-scale Rowe cell
Figure 11 shows the relationships between Uε and Uub for reconstituted and intact Krakowiec clay. It can be seen that both the experimental Uε − Uub and δ − Uub curves have equivalent shapes and can be used to evaluate the test results. The experimental observations indicate that the relationship between Uε and Uub is divergent from the theoretical assumption in most cases. As shown in Fig. 11, the consolidation behaviour of both reconstituted and intact Krakowiec clay is described by the set of nonlinear Uε − Uub curves. The location of these curves depends greatly on the applied vertical effective stress. In case of reconstituted samples under lower vertical effective stress, the Uε − Uub curve is located below the one with higher vertical effective stress. Figure 11 also shows the significant differences in consolidation behaviour of intact clay. The initial states of the two intact samples were significantly different. The initial water content of sample IN1 before being placed inside the consolidation cell was 41%; thus, the sample consistency was close to plastic. On the other hand, initial water content of sample IN2 was 24%, indicating stiff soil consistency. For the stiff sample (IN2), the pore water pressure dissipated very slowly with the consolidation time. An increasing trend in the delayed rate of dissipation in relation to the rate of compression influenced the location of the Uε − Uub curves. Behaviour of these curves for sample with plastic-like consistency (IN1) was similar to that of reconstituted clay. The only difference was that the Uε − Uub curves for sample IN1 were very close together.
The experimental Uε − Uub curves for intact Krakowiec clay indicated greater nonlinearity vis-à-vis reconstituted samples. Typical experimental variations of ΔUε/ΔUub against Uub for investigated soils are shown in Fig. 12. An analysis of the data revealed that the experimental ratios of ΔUε/ΔUub were not constant and greatly differed from each other and from the theoretical constant beyond Uub > 35%. A vast majority of those ratios were higher than the theoretical constant: ΔUε/ΔUub = 0.64. It is also worth noting that ΔUε/ΔUub ratios increased with increase in applied pressure.
Instantaneous consolidation parameters will exploit this feature to precisely identify the end of primary consolidation (EOP); in particular, via the use of δ − Uub, cεv − Uε, cεv − Uub and η − time relationships. Using the δ − Uub relationship, it is possible to isolate the secondary compression from time–compression data, establishing the range of consolidation where the compression develops linearly with the progress of pore water pressure dissipation. At the same time, cεv − Uε and cεv − Uub relationships are useful in studying the nonlinearity in consolidation behaviour due to creep effects. Experimental evidence has shown that the secondary compression actually starts during the dissipation of excess pore water pressure [42, 52]. Thus, the predicted settlement is due to a combination of pore water pressure dissipation during primary compression and secondary compression. The point where the δ − Uub plot deviates from linearity after a certain degree of consolidation was identified as the so-called beginning of secondary compression. It can be demonstrated either by using the cεv − Uub relationship, when both compression and pore pressure data are available, or by using the cεv − Uε relationship, when only compression data are available. To carry out the analysis, a case when both consolidation courses were concurrent with each other was chosen. Therefore, the consolidation curves produced by the three samples under an effective stress of 900 kPa were used for the investigation. Figure 13 shows the consolidation range when compression linearly develops with the progress of pore water pressure dissipation. The relationships between two types of instantaneous cv values are drawn with their mean value (dotted lines), determined on the basis of established consolidation range when these values are constant in Fig. 13d–f. Instantaneous values of cv vary during consolidation. When cv is plotted versus U on a semi-log plot, three different ranges of specific variability may be identified. For compression data, according to Tewatia and Venkatachalam [63], wherever the cεv − U curve is horizontal, the soil follows theoretical behaviour, and wherever the curve exhibits any slope, the soil behaviour is influenced by the initial compression and viscous-plastic effects. The variability in the initial phase of consolidation is determined by the moment of applying load to the sample. (In terms of deformations, this is the primary compression.) At this stage, the coefficient of consolidation demonstrates the threshold values. Then, the values of cv decrease or increase together with the increase in the degree of consolidation and stabilise to a quasi-linear character. It should be noted that slight fluctuations in the course of cεv − U or cuv − U in this phase may be observed. The stabilisation confirms that assumption (iii) is fulfilled, and the point on the curve where the plot deviates from linearity in the middle/advanced stage of consolidation determines the EOP state. Considering that the range with quasi-constant values of cv is identified, a geometric mean of these values can be calculated and compared with those determined by the GR method.
The value of cv calculated in this way is independent of a single measurement point and represents the consolidation behaviour for its significant progress. A comparison of the cv values obtained from the linear part of instantaneous cv versus degree of consolidation plot and those determined by optimisation technique is shown in Fig. 14. Considering the compression data, the ratio of the coefficient of consolidation calculated by the two methods, cquasi-constantv /coptimisedv , was always between 1.0 and 0.5. On the other hand, for pore pressure data, the cquasi-constantv /coptimisedv ratio was between 0.5 and 1.5. The discrepancies obtained in the results between these methods relate to the first and second load increment, where both consolidation rates were significantly different. In case of sample IK1, the initial dissipation rate under effective stress of 900 kPa was much slower than the rate of compression. Drastic decrease in the initial values of the coefficient of consolidation explains the noticed delay in the dissipation rate. In contrast, both consolidation rates for samples IK2 and IK3 were convergent during this stage. As illustrated in Fig. 13e–f, instantaneous values of cv increased up to 20% of the consolidation progress and then stabilised for a considerable period during the advancement of the process. The results of these two samples are quite similar showing the slight predominance of the dissipation rate over compression rate in the middle stage of consolidation. This phenomenon is clearly illustrated in Fig. 13j–l where the factor of dominance, η, assumes negative values with consolidation time. In the later stages of consolidation, instantaneous cv shows a decreasing trend and the η parameter has positive values. As a consequence, the instantaneous values of consolidation parameters clearly describe the extent to which the hydrodynamic and structure/creep factors govern the behaviour of consolidating soil.
4.3.2 Experiments in large-scale Rowe cell
Consolidation tests conducted in the large-scale Rowe cell were carried out to study the effect of coarser fractions on consolidation behaviour because the various mixtures with different size-ratios between fine and coarse particles, χ = Dfine/Dcoarse, represent materials with a different permeability (see Fig. 6). For all mixtures, the plots of void ratio versus hydraulic conductivity yielded a straight line, with the hydraulic conductivity change index, ck, varying between 0.61 and 1.14. As can be seen in Fig. 6, the k values gradually decrease with an increase in the percentage of fine fractions. Similar results were obtained for clay–sand mixtures by Sällfors and Öberg-Högsta [54] and for bentonite–sand mixtures by Sivapullaiah et al. [59] and Castelbaum and Shackelford [6].
Figure 15 shows the relationships between Uε and Uub for mixtures with different size-ratios, χ, between fine and coarse particles. It can be seen that the experimental curves diverge from the theoretical curves and cannot be expressed by a linear line similar to the other fine-grained soils mentioned in the engineering literature [41, 80]. As Fig. 15 shows, all the Uε − Uub curves are located in the lower part of the diagram below the theoretical line. In case of sample RM1 (χ = 0.25), which had fewer but larger voids than the two other mixtures, the pore-size distribution was distinct and the Uε − Uub curves were farther apart from each other. Considering that the fine particles do not fully fill the voids created by coarse fractions, pore water was expelled easier and faster. At higher percentages of fine particles, many more of these particles fill the voids, which cause slower expelling of pore water from the sample and hence longer durations of dissipation. The experimental ratios ΔUε/ΔUub for the three mixtures were not constant and greatly differed from each other and from the theoretical constant of 0.64 (Fig. 16).
Comparison of consolidation rates reveals faster compression rates than dissipation rates in the initial and middle stages of consolidation and much lower rates in the later stages. In the most cases, both curves cross another in the middle or later stage of the process. The mixed behaviour mainly results from nonlinear compressibility of the soil, heterogeneous distribution of pores in the sample and viscous properties. Figure 17 shows the dependence of stress on the rates of consolidation. For clarity, two mixtures with extreme values of χ—the lowest and the highest—were presented. As may be seen from the figure, the Uub − t curves are moving down with the increase in load. Furthermore, results show the shift to the right of the curves for the RM3 sample relative to the curves produced by the RM1 sample. Thus, the rate of compression and dissipation increases with the increase in load and the presence of coarse fraction in the sample.
Figure 18 compares the calculated EOP times for different vertical effective stresses along with the amount of consolidation degree (100 − UEOP) happening within the period from the end of primary consolidation based on the compression–time curve (EOPε) to the end of primary consolidation determined by the excess pore water pressure observations (EOPu). Meaning of this amount can also be expressed by the difference between the time at the end of primary consolidation based on the compression–time curve and the time when dissipation is fully completed. As can be seen from Fig. 18, there is a clear decreasing trend in the value of EOP time with the increase in vertical effective stress. To identify EOP parameters from a single compression curve, the GR method combined with quasi-constant criterion for cv [44, 48] and the CA method were used. The lowest values of EOP times come from the GR method and the highest from the observed completion of dissipation. The very short EOP times determined by the GR method result from very short periods of consolidation when the instantaneous cv based on compression takes constant values. The EOP times determined on the basis of CA method were on average 5.5, 3.8 and 3.9 times lower than those determined by the completion of the dissipation, for sample RM1, RM2 and RM3, respectively. In all considered cases, the remaining pore water pressure at the EOP state determined by compression–time curve induces the additional compression of mixtures due to uncompleted dissipation. The latter observation very much affects the (100 − UEOP values). The (100 − UEOP) values depend greatly on the method used for determining EOP state based on the compression–time curve. These values based on the CA method do not exceed 25%. In comparison, the optimisation approach gave values mostly within a range of 25% to 95%. The high percentage of remaining pore water pressure associated with the GR method may indicate a large amount of creep contribution to the total consolidation settlement. The (100 − UEOP) values determined on the basis of CA method confirm the experimental evidence given by Zeng et al. [69] for the four kinds of clays with liquid limit within a spectrum ranging from 43.8% to 70.8%. Nevertheless, the EOP state determined by graphical matching procedure, like the CA method, is not a true end of primary consolidation theoretically [39, 44, 64]. Creep acting during the primary consolidation phase significantly shortens EOP times, both for clay–sand mixtures and fine-grained soils. In general, the (100 − UEOP) values increase with an increase in vertical effective stress. As shown in Fig. 18b, the highest values of (100 − UEOP) were obtained for sample RM1 (χ = 0.25) and varied between 94.2% and 94.7%, excluding the vertical effective stress of 25 kPa. The behaviour of sample RM2 (χ = 0.50) was very similar, except that the (100 − UEOP) values were lower. For sample RM3 (χ = 0.75), a clear increasing trend in the value of (100 − UEOP) was noted. On the contrary, scattered data were produced through the Casagrande procedure. No regularity was found in terms of the location of the Uε − Uub curves on the plot with the value of 100 − Uubo, where Uubo is the amount of consolidation degree happening within the period from the end of primary consolidation determined by the optimisation of the compression–time curve to the end of primary consolidation determined by the excess pore water pressure.
Figure 19 shows distributions of instantaneous cv determined from a compression–time curve with the degree of dissipation at the base, Uub. For all mixtures, instantaneous cv linearly decreases in the middle stage of dissipation, excluding the first load increment (effective vertical pressure of 25 kPa). As shown in Fig. 19, the sample with the highest content of sand fraction (χ = 0.25) has higher values of cv, and the highest rate of change during dissipation compared to the remaining two samples with χ = 0.50 and χ = 0.75. For all cases, the values of instantaneous cv decrease with the increase in clay content in the mixture. Thus, the higher the value of χ, the higher the values of instantaneous cv. Moreover, the behaviour of cv − Uub curves in later stages of consolidation, when Uub > 85%, indicates significant creep effect, illustrated by the drastic decrease in cv values. Similar trend was also observed for intact and reconstituted Krakowiec clay and other fine-grained soils investigated in the present work. A possible explanation for this observation is a substantial increase in heterogeneity due to the presence of coarse fraction, spatial distribution patterns of the soil pores, length of the drainage paths, nonlinear compressibility and duration of the loading time. The η parameter changed in all the analysed samples. In the initial and middle stages of consolidation, the η values were positive and in the later stages were close to 0 or negative. This demonstrates improvement in the conditions for the pore pressure dissipation during consolidation.
5 Conclusions
Phenomenon of compression development during dissipation of the excess pore water pressure was investigated based on available world test data as well as main experiments on various types of fine-grained soils. Based on the experimental results and discussion presented in the previous sections, main conclusions are drawn as follows:
-
1.
Theoretical unique relationship between average degree of consolidation and degree of dissipation is not valid for considered soils. For a given soil, above Uub > 35%, the Uε − Uub relationship is formed by a set of curves corresponding to different load increments.
-
2.
The nonlinearity between compression and pore water pressure results from the impact of two major governing factors in consolidation. All the experiments demonstrate that the resistance of soil structure/creep factor and permeability has come to be recognised as playing interacting roles in consolidation.
-
3.
Prior to the GR method, the cv can be derived based on the compression and pore water pressure data. The proposed approach utilises the combination of the complete range of theoretical and experimental consolidation courses. The determination of cv by an existing methods is attributed to the use of specific points on consolidation curve, while in the GR method, a representative average consolidation rate is considered. The optimal values of cv in significant cases are consistent with those determined on the basis of constancy criterion for cv. Moreover, GR method facilitates the comparison of the laboratory dissipation data with the piezocone dissipation test results.
-
4.
Instantaneous consolidation parameters vary during the process and may describe the extent to which the hydrodynamic and structure/creep factors govern the consolidation of soil. The size of the coarser fraction plays an important role in controlling the consolidation rates. For the investigated clay–sand mixtures, values of instantaneous cv decrease with the increase in clay content in the mixture.
-
5.
EOP times determined based on the compression and dissipation of pore water pressure have a clear decreasing trend with the increase in vertical effective stress. The EOP time strongly depends on the method used with the following decreasing order: excess pore water pressure observations > CA method > GR method.
-
6.
The amount of consolidation degree (100 − UEOP) happening within the period from the end of primary consolidation based on the compression–time curve to the end of primary consolidation determined by the excess pore water pressure ambiguously determine the location of the Uε − Uub curve on the plot. However, the Uε − Uub curves for low-permeability clay–sand mixture lie above that for the high-permeability mixture. The (100 − Uubc) values determined according to the CA method were significantly lower than the (100 − Uubo) values determined by the optimisation approach. Moreover, the amount of (100 − Uubo) for the mixtures show decreasing trend with the decrease in permeability.
Abbreviations
- CA:
-
Casagrande method
- cv :
-
Coefficient of consolidation
- cεv :
-
Instantaneous coefficient of consolidation based on compression
- cuv :
-
Instantaneous coefficient of consolidation based on pore water pressure
- e0 :
-
Initial void ratio
- ei :
-
Void ratio at time t
- ESCS:
-
European Soil Classification System
- GR:
-
Gradient-based method
- I:
-
Intact sample
- Ip :
-
Plasticity index
- LIR:
-
Load increment ratio
- M:
-
(2 m + 1)π/2
- m:
-
Integer
- MSL:
-
Multiple-stage loading test
- PTIB:
-
Porous top impermeable boundary
- R:
-
Reconstituted sample
- t:
-
Time variable
- Tv :
-
Non-dimensional time factor
- u:
-
Pore water pressure
- u0 :
-
Pore water pressure at the initial stage of consolidation
- ui :
-
Pore water pressure at time t
- uf :
-
Final pore water pressure
- Uε :
-
Average degree of consolidation
- Un,i :
-
Experimental degree of consolidation
- U*n,i :
-
Theoretical degree of consolidation
- Uub :
-
Degree of dissipation at base
- wL :
-
Liquid limit
- wn,i :
-
Range around each theoretical point U*n,i characterising the divergence
- wp :
-
Plastic limit
- z:
-
Distance from the top of the sample subjected to consolidation
- η:
-
Factor of dominance
- εi :
-
Strain at time t
- εf :
-
Final strain at the end of excess pore water pressure dissipation under the given load increment
- χ:
-
Size-ratio between fine and coarse particles
References
Aboshi H (1973) An experimental investigation on the similitude in the consolidation of a soft clay, including the secondary creep settlement. In: Proceedings of 8th ICSMFE, Moscow 4(3), 88
Ansari Y, Merifield R, Sheng D (2014) A Piezocone dissipation test interpretation method for hydraulic conductivity of soft clays. Soils Found 54(6):1104–1116. https://doi.org/10.1016/j.sandf.2014.11.006
Berre T, Iversen K (1972) Oedometer tests with different specimen heights on a clay exhibiting large secondary compression. Géotechnique 22(1):53–70. https://doi.org/10.1680/geot.1972.22.1.53
Blewett J, McCarter WJ, Chrisp TM, Starrs G (2002) An automated and improved laboratory consolidation system. Can Geotech J 39(3):738–743. https://doi.org/10.1139/t02-029
Casagrande A, Fadum RE (1940) Notes on soil testing for engineering purposes, Harvard Soil Mechanics Series, No. 8, Cambridge, Massachusetts, MA, p 71
Castelbaum D, Shackelford CD (2009) Hydraulic conductivity of bentonite slurry mixed sands. J Geotech Geoenviron Eng ASCE 135:1941–1956. https://doi.org/10.1061/(ASCE)GT.1943-5606.0000169
Chai JC, Sheng D, Carter JP, Zhu H (2012) Coefficient of consolidation from non-standard piezocone dissipation curves. Comput Geotech 41(2012):13–22. https://doi.org/10.1016/j.compgeo.2011.11.005
Choi YK (1982) Consolidation behaviour of natural clays. Dissertation, University of Illinois
Christie IF (1965) Secondary compression effects during one-dimensional consolidation tests. In: Proceedings, 6th ICSMFE, Montreal, 1, pp 198–202
Chung SG, Kweon HJ, Jang WY (2014) Hyperbolic Fit Method for interpretation of piezocone dissipation tests. J Geotech Geoenviron Eng ASCE 140(1):251–254. https://doi.org/10.1061/(ASCE)GT.1943-5606.0000967
Crawford CB (1986) State of the art: Evaluation and interpretation of soil consolidation tests. In: Yong RN, Townsend FC (eds) Consolidation of soils: testing and evaluation, ASTM STP 892, ASTM International, pp 71–103
Degago SA, Grimstad G, Jostad HP, Nordal S, Olsson M (2011) Use and misuse of the isotache concept with respect to creep hypotheses A and B. Géotechnique 61(10):897–908. https://doi.org/10.1680/geot.9.P.112
Den Haan EJ (1996) A compression model for non-brittle soft clays and peat. Géotechnique 46(1):1–16. https://doi.org/10.1680/geot.1996.46.1.1
Dobak P, Gaszyński J (2015) Evaluation of soil permeability from consolidation analysis based on Terzaghi’s and Biot’s theory. Geol Q 59(2):373–381. https://doi.org/10.7306/gq.v59i1.11037
EN ISO 14688-2 (2018) Geotechnical investigation and testing—Identification and classification of soil—Part 2: Principles for a classification. Comité Européen de Normalisation, Brussels
Feng TW (1991) Compressibility and permeability of natural soft clays and surcharging to reduce settlements. Dissertation, University of Illinois
Gibson RE (1963) An analysis of system flexibility and its effect on lime lag in pore-water pressure measurements. Géotechnique 13(1):1–9. https://doi.org/10.1680/geot.1963.13.1.1
Graham J, Crooks JH, Bell AL (1983) Time effects on the stress-strain behaviour of natural soft clays. Géotechnique 33(3):327–340. https://doi.org/10.1680/geot.1983.33.3.327
Grimstad G, Degago SA, Nordal S, Karstunen M (2010) Modeling creep and rate effects in structured anisotropic soft clays. Acta Geotech 5(1):69–81. https://doi.org/10.1007/s11440-010-0119-y
Head KH (1998) Manual of soil laboratory testing: effective stress tests. Wiley, New York
Hueso G (2017) Pore water pressure behaviour and evolution in clays and its influence in the consolidation process. Dissertation, Aalto University
Jang WY, Chung SG, Kweon HJ (2015) Estimation of coefficients of consolidation and permeability via piezocone dissipation tests. KSCE J Civ Eng 19(3):621–630. https://doi.org/10.1007/s12205-013-1418-2
Jin YF, Yin ZY, Riou Y, Hicher PY (2017) Identifying creep and destructuration related to soil parameters by optimization methods. KSCE J Civ Eng 21(4):1123–1134. https://doi.org/10.1007/s12205-016-0378-8
Jin YF, Yin ZY, Wu ZX, Zhou WH (2018) Identifying parameters of easily crushable sand and application to offshore pile driving. Ocean Eng 154:416–429. https://doi.org/10.1016/j.oceaneng.2018.01.023
Joseph PG (2014) Viscosity and secondary consolidation in one-dimensional loading. Geotech Res 1(3):90–98. https://doi.org/10.1680/gr.14.00008
Joseph PG (2017) Dynamical systems-based soil mechanics. Taylor & Francis, Abingdon
Kabbaj M, Tavenas F, Leroueil S (1988) In situ and laboratory stress-strain relationships. Géotechnique 38(1):83–100. https://doi.org/10.1680/geot.1988.38.1.83
Khan MA, Garga VK (1994) A simple design for hydraulic consolidometer and volume gauge. Can Geotech J 31:769–772. https://doi.org/10.1139/t94-087
Kim YT, Leroueil S (2001) Modeling the viscoplastic behaviour of clays during consolidation: application to Berthierville clay in both laboratory and field conditions. Can Geotech J 38(3):484–497. https://doi.org/10.1139/t00-108
Kovačević M, Jurić-Kaćunić D, Librić L, Ivoš G (2018) Engineering soil classification according to EN ISO 14688-2:2018. Gradevinar 70(10):873–879. https://doi.org/10.14256/JCE.2437.2018
Krage CP, DeJong JT, Schnaid F (2015) Estimation of the coefficient of consolidation from incomplete cone penetration test dissipation Tests. J Geotech Geoenviron Eng. https://doi.org/10.1061/(ASCE)GT.1943-5606.0001218
Laaksonen S (2014) Improvement of research methods and testing equipment for deformation properties of clay. Dissertation, Aalto University
Leonards GA, Girault P (1961) A study of the one-dimensional consolidation test. In: Proceedings of 9th ICSMFE, Paris, 1, 116–130
Levasseur S, Malécot Y, Boulon M, Flavigny E (2008) Soil parameter identification using a genetic algorithm. Int J Numer Anal Met 32(2):189–213. https://doi.org/10.1002/nag.614
Leoni M, Karstunen M, Vermeer PA (2008) Anisotropic creep model for soft soils. Géotechnique 58(3):215–226. https://doi.org/10.1680/geot.2008.58.3.215
Leroueil S (1987) Tenth Canadian geotechnical colloquium: recent developments in consolidation of natural clays. Can Geotech J 25(1):85–107. https://doi.org/10.1139/t88-010
Leroueil S, Kabbaj M, Tavenas F, Bouchard R (1985) Stress-strain-strain rate relation for the sensitive natural clays. Géotechnique 35(2):159–180. https://doi.org/10.1680/geot.1985.35.2.159
Lovisa J, Read W, Sivakugan N (2011) A critical reappraisal of the average degree of consolidation. Geotech Geol Eng 29:873–879. https://doi.org/10.1007/s10706-011-9424-y
Lovisa J, Sivakugan N (2012) An in-depth comparison of cv values determined using common curve-fitting techniques. Geotech Test J 36(1):30–39. https://doi.org/10.1520/GTJ20120038
Mesri G (1987) Fourth law of soil mechanics: a law of compressibility. In: Proceedings of international symposium on geotechnical engineering of soft soils, 2, Mexico City, Mexico, pp 179–187
Mesri G, Choi YK (1984) Discussion of Time effects on the stress-strain behavior of natural soft clays by Graham, Crooks. Bell Géotech 34(3):433–444. https://doi.org/10.1680/geot.1984.34.3.433
Mesri G, Huvaj N, Vardhanabhuti B, Ho YH (2005) Excess porewater pressure during secondary compression. In: Proceedings of 16th international conference on soil mechanics and geotechnical engineering, Osaka 2, pp 1087–1090
Northey RD, Thomas RF (1965) Consolidation test pore pressures. In: Proceedings, 6th ICSMFE, Montreal, 1, pp 323–327
Olek BS (2018) Consolidation analysis of clayey soils using analytical tools. Acta Geotech Slov 2018(2):58–73. https://doi.org/10.18690/actageotechslov.15.2.58-73.2018
Olek BS (2019) Critical reappraisal of Casagrande and Taylor methods for coefficient of consolidation. KSCE J Civ Eng 23(9):3818–3830. https://doi.org/10.1007/s12205-019-1222-8
Olek BS, Dobak P, Gaszyńska-Freiwald G (2018) Sensitivity evaluation of Krakowiec clay based on time-dependent behavior. Open Geosci 10(1):718–725. https://doi.org/10.1515/geo-2018-0057
Olek BS, Pilecka E (2019) Large-scale Rowe cell experimental study on coefficient of consolidation of coal mine tailings. In: Proceedings of 5th international scientific conference on civil engineering-infrastructure-mining, E3S Web of Conferences 106, 01004, https://doi.org/10.1051/e3sconf/201910601004
Olek BS, Woźniak H (2016) Determination of quasi-filtration phase of consolidation based on experimental and theoretical course of the uniaxial deformation and distribution of pore pressure. Geol Geophys Environ 42(3):353–363. https://doi.org/10.7494/geol.2016.42.3.353
Olson R (1986) State of the art: consolidation testing. In: Yong R, Townsend F (eds) Consolidation of soils: testing and evaluation. West ASTM International, Conshohocken, pp 7–70. https://doi.org/10.1520/STP34606S
Perloff WH, Nair K, Smith JG (1965) Effect of measuring system on pore water pressures in the consolidation test. In: Proceedings, 6th ICSMFE, Montreal, 1, pp 338–341
Robinson RG (1999) Consolidation analysis with pore water pressure measurements. Géotechnique 49(1):127–132. https://doi.org/10.1520/JTE12362J
Robinson RG (2003) A study on the beginning of secondary compression of soils. J Test Eval 31(5):388–397. https://doi.org/10.1520/JTE12362J
Robinson RG, Soundara B (2008) Coefficient of consolidation from mid-plane pore pressure measurements. Int J Geotech Eng 2(4):419–425. https://doi.org/10.3328/IJGE.2008.02.04.419-425
Sällfors G, Öberg-Högsta AL (2002) Determination of hydraulic conductivity of sand-bentonite mixtures for engineering purposes. Geotech Geol Eng 20:65–80. https://doi.org/10.1023/A:1013857823676
Schnaid F, Sills GC, Soares JM, Nyirenda Z (1997) Predictions of the coefficient of consolidation from piezocone tests. Can Geotech J 34(2):315–327. https://doi.org/10.1139/t96-112
Shogaki T, Kaneko M (1993) Evaluation of consolidation parameters by graphical method. In: Proceedings of the 3rd international conference on case histories in geotechnical engineering, St. Louis, Missouri, June 1–4, paper no. 13.08
Shukla S, Sivakugan N, Das B (2009) Methods for determination of the coefficient of consolidation and field observations of time rate of settlement—an overview. Int J Geotech Eng 3(1):89–108. https://doi.org/10.3328/IJGE.2009.03.01.89-108
Sills GC, Hird CC (2005) Coefficient of consolidation from piezocone measurements. Géotechnique 55(8):597–602. https://doi.org/10.1680/geot.2005.55.8.597
Sivapullaiah P, Sridharan A, Stalin V (2000) Hydraulic conductivity of bentonite-sand mixtures. Can Geotech J 37(2):406–413. https://doi.org/10.1139/t99-120
Taylor DW (1942) Research on consolidation of clays. Department of Civil Sanitary Engineering, Massachusetts Institute of Technology, Cambridge, Massachusetts
Taylor DW, Merchant W (1940) A theory of clay consolidation accounting for secondary compression. Journal of Mathematics and Physics 19(1–4):167–185. https://doi.org/10.1002/sapm1940191167
Terzaghi K, Fröhlich OK (1936) Theorie der Setzung von Tonschichten. Franz Deuticka, Vienna
Tewatia SK, Venkatachalam K (1997) Discussion on `Consolidation behavior of clayey Soils’ by Sridharan, Prakash and Asha. Geotech Test J 20(1):126–128. https://doi.org/10.1520/GTJ11427J
Tewatia SK (1998) Evaluation of true cv and instantaneous cv, and isolation of secondary consolidation. Geotech Test J 21(2):102–108. https://doi.org/10.1520/GTJ10748J
Tewatia SK, Bose SK, Sridharan A, Rath S (2007) Stress induced time dependent behavior of clayey soils. Geotech Geol Eng 25(2):239–255. https://doi.org/10.1007/s10706-006-9107-2
Vinod JS, Sridharan A (2015) Laboratory determination of coefficient of consolidation from pore water pressure measurement. Geotech Lett 5:294–298. https://doi.org/10.1680/jgele.15.00136
Wahls HE (1962) Analysis of primary and secondary consolidation. J Soil Mech Found Div Am Soc Civ Eng 88(6):207–234
Watabe Y, Udaka K, Morikawa Y (2008) Strain rate effect on long-term consolidation of Osaka Bay Clay. Soils Found 48(4):495–509. https://doi.org/10.3208/sandf.48.495
Wen YX, Shi JY (2005) Delay of pore pressure in oedometer and its effect on determination of coefficient of consolidation. Chin J Rock Mech Eng 24(2):357–363
Whitman RV, Richardson AM, Haley KA (1961) Time-lags in pore pressure measurements. In: Proceedings, 5th ICSMFE, Paris, 1, pp 407–411
Yin JH, Zhu JG (1999) Elastic viscoplastic consolidation modelling and interpretation of pore-water pressure responses in clay underneath Tarsiut Island. Can Geotech J 36(4):708–717. https://doi.org/10.1139/t99-041
Yin JH, Zhu JG, Graham J (2002) A new elastic viscoplastic model for time-dependent behaviour of normally and overconsolidated clays: theory and verification. Can Geotech J 39(1):157–173. https://doi.org/10.1139/t01-074
Yin ZY, Chang CS, Karstunen M, Hicher PY (2010) An anisotropic elastic–viscoplastic model for soft clays. Int J Solids Struct 47(5):665–677. https://doi.org/10.1016/j.ijsolstr.2009.11.004
Yin ZY, Hicher PY (2008) Identifying parameters controlling soil delayed behaviour from laboratory and in situ pressuremeter testing. Int J Numer Anal Met 32(12):1515–1535. https://doi.org/10.1002/nag.684
Yin ZY, Jin YF, Huang HW, Shen SL (2016) Evolutionary polynomial regression based modelling of clay compressibility using an enhanced hybrid real-coded genetic algorithm. Eng Geol 210:158–167. https://doi.org/10.1016/j.enggeo.2016.06.016
Yin ZY, Karstunen M, Chang CS, Koskinen M, Lojander M (2011) Modeling time-dependent behavior of soft sensitive clay. J Geotech Geoenviron Eng ASCE 137(11):1103–1113. https://doi.org/10.1061/(ASCE)GT.1943-5606.0000527
Yin ZY, Xu Q, Yu C (2012) Elastic viscoplastic modeling for natural soft clays considering nonlinear creep. Int J Geomech. https://doi.org/10.1061/(ASCE)GM.1943-5622.0000284
Yin ZY, Zhu QY, Zhang DM (2017) Comparison of two creep degradation modeling approaches for soft structured clays. Acta Geotech 12(6):1395–1413. https://doi.org/10.1007/s11440-017-0556-y
Zeng LL, Hong ZS (2015) Experimental study of primary consolidation time for structured and destructured clays. Appl Clay Sci 116–117:141–149. https://doi.org/10.1016/j.clay.2015.08.027
Zeng LL, Hong ZS, Han J (2018) Experimental investigations on discrepancy in consolidation degrees with deformation and pore pressure variations of natural clays. Appl Clay Sci 152:38–43. https://doi.org/10.1016/j.clay.2017.10.029
Zhu QY, Yin ZY, Hicher PY, Shen SL (2015) Non-linearity of one-dimensional creep characteristics of soft clays. Acta Geotech 11(4):887–900. https://doi.org/10.1007/s11440-015-0411-y
Zhu QY, Yin ZY, Zhang DM, Huang HW (2017) Numerical modeling of creep degradation of natural soft clays under one-dimensional condition. KSCE J Civ Eng 21:1668–1678. https://doi.org/10.1007/s12205-016-1026-z
Zou SF, Xie XY, Li JZ, Wang ZJ, Wang HY (2019) Rheological characteristics and one-dimensional isotache modelling of marine soft clays. Mar Georesour Geotec 37(6):660–670. https://doi.org/10.1080/1064119X.2018.1473903
Funding
Not applicable.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Olek, B.S. Experimental insights into consolidation rates during one-dimensional loading with special reference to excess pore water pressure. Acta Geotech. 15, 3571–3591 (2020). https://doi.org/10.1007/s11440-020-01042-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11440-020-01042-3