1. Introduction
Railway infrastructure consists of a track superstructure (namely rails and associated components) and substructure which support these rails (ballast, sub-ballast, and subgrade), as shown in
Figure 1a,b. Much research has gone into minimising the wear on the rail–wheel interface [
1,
2]. This wear is also known to be a product of the quality of the track substructure. This supporting structure needs to be durable to minimise ongoing maintenance and to optimise the use of materials such as concrete and ballast from an environmental perspective. The performance of the overall track design also depends on the behaviour of the ground (natural or remediated) over which the railway is constructed.
In the UK there exist large expanses of non-engineered backfills, specifically a historic product of the coal mining industry. Many of the coal-rich layers are interspersed with mudrocks [
3], leading to the creation of areas of non-engineered backfill where the mudrock spoil is placed. The initial inundation collapse [
4,
5] and subsequent behaviour [
6] of these fills is well-documented, but what remains unknown is their response to cyclic loading brought about by railway construction over these now-remediated areas.
The dynamic response of the overall track strongly depends on the properties of individual elements of the track structure and the interaction between train movement and underlying soil [
7]. With all laboratory testing, the stress conditions recreated should represent the physical conditions present in the problem to be investigated. For track subgrades this is a combination of the vertical stresses applied by the substructure above the point of interest and the dynamic stresses induced by railway traffic. Kempfert et al. [
8] reported that the in situ dynamic stresses induced by railway traffic were dependant on train speed, type of substructure, depth, and soil type, as shown in
Figure 1d. Dynamic stress levels were reported to be the highest in ballasted track, reaching a peak of ≈50 kPa, 0.86 m from the surface directly under the rail location, to a minimum of 5 kPa at a depth of 1.48 m below. It was also found there was an attenuation of the induced dynamic stresses with increasing depth. Bian et al. [
9] found that the impact of dynamic stress on depth extends much deeper in ballasted tracks and that the stresses range between 50–100 kPa, whilst in the ballastless tracks this is reduced to 13–20 kPa. A comparison of the stress conditions experienced by the subgrade is shown schematically in
Figure 1. Bian et al. also found that whilst the train speed had an effect on the stresses generated, this was a second order effect when compared with the attenuation with depth.
To find an adequate design against long-term track deterioration, the response of the soil under repeated loading must be quantified. The resistance of a track subsoil to cyclic loading can be characterised by measuring the resilient modulus for a given stress state. To assess the performance of a subgrade, the cyclic triaxial test is used to estimate the stiffness (resilient modulus) and strength characteristics of the soil.
For design purposes, it is important to consider how the materials involved in the design react and how the resilient behaviour varies with changes in various influencing factors. Fredlund et al. [
10] proposed a theory between resilient modulus and stress conditions for cohesive subgrade soils and established the relationship between resilient modulus and stress state for specimens subjected to 100 stress cycles. Resilient modulus was found to be affected by an increase in deviator stress and matrix suction. Whilst numerical models also exist to predict the long-term cyclic deterioration of railway tracks [
11], physical test data is always required to inform the models.
The dynamic load that is induced from the movement of the train can be considered according to a theoretical analysis of a stress wave penetration into the soil. This load, applied from the passage of the wheels, generates stress pulses in the soil. Each pulse includes three components: vertical, horizontal, and shear, causing rotation of the principal stress axes [
12]. This has lead researchers to use the hollow cylinder apparatus to investigate this [
13].
At the start of a test, particle rotation and rearrangement produce the plastic strain. Thus, with an increase in the number of cycles, the particle movements become limited and continued strain reduces due to the increased particle contacts. Previous studies have indicated that a large number of cycles is not required for certain soil types [
14]. However, there is no pre-defined number of cycles for required for this stabilization to occur. Stewart [
15] achieved stabilization after 1000 cycles for a typical ballast material, while Lackenby [
16] indicated that stabilization occurred at 100 cycles for granular materials. Suiker et al. [
17] tested granular soils with up to 5 million cycles with stability occuring after 1000, supporting the work of Stewart. However, for these granular materials, the durability of the individual particles is high, unlike that of mudrock [
18]. Thus, the number of cycles required for stabilisation depends on material type, water content, and stress level and will be investigated for mudrocks in the current study.
This paper presents the results of two studies. The first is a study on the behaviour of track type (ballasted or ballastless) induced states on the resilient modulus. The second study is an extension of this to include higher stress states in an attempt to generalise the results.
2. Materials and Methods
The material of study, mudrock colliery spoil, was collected on 10 August 2015 from Kellingley Colliery, North Yorkshire, England. This was stored in a covered crate outside the research laboratory at the University of Sheffield from collection. This material can be described as a weathered dark grey mudrock and has a variety of particle sizes to a maximum of 30 mm. According to the triaxial cyclic load testing protocol given in [
19], the maximum particle size allowed in a test is 1/6 of the diameter of the triaxial cell to be utilised. In the current testing, a 100 mm diameter cell was used, which gives a maximum particle size of 16 mm. Particles bigger than 10 mm were removed due to their angular shape, which led to difficulties when compacting specimens. The effect of compaction was also investigated in the current study to enable the influence of degradation on performance to be quantified. Thus, samples produced with only <5 mm particles were chosen to shed light on the effect of degradation on the cyclic performance. Particle size distribution tests were undertaken, showing that the spoil could be classified as poorly-graded for the <10 mm and <5 mm samples for the results shown in
Figure 2. The values of
,
, and
are 4.6, 8.0, and 10.4 mm, respectively, for the as-received material. The specific gravity,
, was found to be 2.75. The coefficient of uniformity (
=
/
) and the coefficient of curvature (
= (
)
/(
)) are given in
Table 1 after an indicative cyclic test, due to the continued particle degradation.
Figure 2 displays the effect of compaction and cycling on the degradation of the mudrock. The mudrock was sieved to prepare for compaction and then compacted to be ready for the test. Specimens were dried in the oven after compaction and sieved again. It can be seen that the change of particle size distribution after compaction was 56% at
. It can be seen that there is a change of particle size distribution after compaction, compared with only a minor further reduction in size.
The permeability,
k, calculated for this material is based on the empirical relationship given by [
20]:
where SF is the shape factor (ranging from 6.0 for spherical to 8.4 for angular) and
e is the void ratio. For
i sieve pairs used,
is the larger size and
is the smaller, with
being the fraction of particles between two sieve sizes. Following Equation (
1), the permeability for the compacted particles passing through a 10 mm sieve was 0.0337 m/s and for particles passing through a 5 mm sieve was 0.0203 m/s. Hence, the soil was classified as being semi-pervious or having a moderate permeability [
21].
To assess the durability of the larger particles, slaking tests were performed [
22]. The results classify the mudrock as having medium slake durability.
Figure 3 shows the degradation of the soaked particles with repeated slaking cycles.
All tested specimens were compacted according to the information given in
Table 2. Each saturated specimen was saturated prior to testing, representing the worst case scenario that could occur due to fluctuations in the groundwater table. In the saturated condition, the B-value was 0.95–0.96, guaranteeing the specimens were close to full saturation. The specimens were tested under two conditions: partially saturated and saturated cases. In the UK, High Speed Rail 1 (HS1) trains run at speeds between 230 km/h (143 mph) to 300 km/h (186 mph) with a train length of 108 m. In this study, load frequencies of 4 Hz and 1 Hz were used for testing and are indicative of the frequencies induced by HS1.
The triaxial testing system was manufactured by ELE International, UK, and Industrial Process Controls Ltd. The system consists of a triaxial cell, a load frame and a Control and Data Acquisition System (CDAS) from UTM, linked to a computer. The triaxial cell can test specimens of up to 200 mm high and 100 mm in diameter with a suction top cap allowing a constant connection to the sample top. The cyclic triaxial system is shown in
Figure 4. Details of the triaxial cyclic load control software can also be found in [
23]. Stresses were applied for each sample as shown in
Table 3, based on [
8,
9].
3. Experimental Issues
In the UTM apparatus control software, loading is applied continuously until either the termination strain level is exceeded or it is stopped manually by the operator. To apply a compressive sinusoidal load, the loading pulse wave shape was set in the UTM software to be haversine. The storage of information in the UTM software depends on the loading rate and loading sequence. For a test consisting of 10
cycles, the software only stores 626 data points. This is hard-programmed into the software and is not user configurable. The software was originally designed for slow cycles taking many seconds, not for thousands of cycles at high frequency [
24]. To collect as much data as possible, 10
cycles were applied for two different frequencies.
In the 1 Hz tests, the first 500 cycles were captured, each being represented by a single data point. The data are then not stored until 64,128 cycles, at which time each data point from cycle 64,128 to 10
represents an average of 128 cycles. Testing at 4 Hz, each data point represents the average of 5 cycles, which is maintained for the first 2496 cycles. The data is then not stored until 80,156 cycles, at which time each data point from 80,156 to 10
cycles each data point represents the average response over 160 cycles. The resilient modulus was calculated from the average data in each case, with the results being shown in
Figure 5.
In
Figure 5a–d, the first hundred data points are plotted raw. From 106 to 2496 cycles the data points represent the average resilient modulus, with the standard deviation shown as the shaded area. The same is true for the data points between 80,156 and 10
cycles data where the average with standard deviation was again plotted. In
Figure 5e,f, the first hundred data points are again plotted raw with the remaining data points representing the average resilient modulus for 1000 cycles. Again, the shaded areas represent the standard deviation.
5. Discussion
The current findings show that an increase in cyclic deviatoric stress with a constant confining pressure will act to increase the resilient modulus. To better understand the trends in the data, the resilient modulus for all tests were compared using stress ratio (
) and were plotted versus the
attained at
cycles in
Figure 7a,b. The stress ratio varied from 2.14 to 0.16, according to the conditions simulated (
Table 3). With high stress ratios (
), the resilient modulus is relatively stable. In this region the particle size affected the attained modulus for 1 Hz and 4 Hz frequencies by reducing the
by 4% and 11%, respectively, for a reduction in the maximum particle size from 10 to 5 mm. It can also be seen that the
was higher for increased load frequency.
For stress ratios between 0.4 and 1, the performance improved as the attained modulus was higher in all like-for-like tests. The highest stiffness of any test was developed in the 1 Hz under OMC conditions for particles < 10 mm. For stress ratios below 0.4, all the specimens exhibited low resilient modulus.
Generally speaking, the resilient modulus increased with a decrease in stress ratio until reaching 0.31, at which point the specimens became less stiff for any given moisture content condition. In addition, decreasing stress ratio under the same confining pressure led to a decrease in resilient modulus stress ratio (see results at 1.07 and 0.31).
The value of resilient modulus for mudrock can be classified as a ‘good’ modulus according to the classification for track and subgrade modulus [
25]. The results indicate that an increase in cyclic deviatoric stress leads to an increase in stiffness (
). Nevertheless, this does not mean a stiffer layer would behave badly due to higher cyclic deviator stress because the performance of soil not only depends on stress state but also on the strength of soil. In the comparison between ballasted and ballastless stress distributions, it was shown that the resilient modulus for ballasted systems was larger than that in ballastless due to the deviator stress being higher. This is due to the increment of strength being much higher than the increase in deviator stress [
26].
6. Conclusions
It is well known that the resilient modulus, , can be used to quantify the long-term cyclic performance of soils. In this paper, the resilient modulus has been used to quantify the long-term response of soils under varying distributions of stress.
The stress distributions that were induced below ballasted and ballastless track structures were estimated from the literature and specimens were tested under the same stress states in the laboratory. Cyclic deviator stresses are lower in ballastless track types than in ballasted as the thickness of the first layer is higher, which spreads the loading and reduces the stress.
Results of the slaking test and compaction particle size distribution data showed that breakage led to an increase in fine content after compaction. Hence, soil permeability could also be affected, which could lead to the soil not meeting the design requirements. Filter materials could be used in this case to maintain drainage in the soil. Further research is needed to conduct seepage tests under the same conditions as in the field, to investigate the performance of drains, and therefore guarantee track performance.
Results showed that mudrock subjected to the stress distribution for a ballastless system had a modest decrease in stiffness of around 6% compared to that seen in the ballasted stress state. However, increasing deviatoric stress and confining pressure led to a decrease of the stiffness of the ballastless track to around 54%. In addition, the effect of changing stress distribution on the resilient modulus was highlighted. The results showed that stiffness increases with a decrease in the stress ratio until the maximum at 0.43 (higher deviatoric stress is reached). The then decays by around 50–55% for stress ratios down to 0.134.
A ballastless track system can be capable of reducing the amount of maintenance required by 10–30% compared to ballasted track. However, the the stress conditions generated by ballasted track showed a greater suitability for use in design in terms of the stiffness generated in the subgrade. Ballastless produces less settlement due to the cumulative strain being dependent mainly on the deviatoric stress. This is particularly the case for the smaller particles, as bigger particles are more resistant to breakage and densification with further cycles. This conclusion supports previous work done by [
27,
28,
29].
To make good use of the results of the cyclic triaxial tests for the possible use of mudrock as a subgrade (or more likely as an existing non-engineered backfill), it is necessary to take into account the traffic weight, maintenance schedule, and allowable values of elastic and plastic deformations of the subgrade to determine the appropriate parameters and structure of the subgrade.
The properties of the subgrade soil is the most important factor that influences the track modulus compared with the other track components [
30]. Design of an adequate track railway should prevent subgrade progressive shear failure and excessive plastic deformation. These problems cause excessive track maintenance. In this research, the behaviour of mudrock has been examined under repeated loading and showed improvement during these cycles. However, the resilient modulus generated is only classified as medium stiffness and strength, and should be designed accordingly.