Abstract

Cutter performance evaluation is important for shield TBM during the design and refurbishment stage. To face the challenges of choosing the proper cutters for tunneling in complex condition, according to the concept of parameter profile analysis, a systematic evaluation method was proposed. In this novel method, by comparing with their expected best value and the corresponding unacceptable limit, all of the selected performance parameters can be synthesized to assess the proximity of the overall merit of each cutter with respect to all the performances considered under all possible geological conditions. Performance indexes including cutting efficiency, structural strength, wear life, and dynamic response were individually analyzed based on linear cutting tests, finite element analyses, and theoretical calculations. Finally, a case study was carried out to demonstrate how the method is applied to find the optimal cutter among a small-scale disc cutter and two scrapers used for cutting multiple soft rock. In this case, three types of concrete specimens with distinct mechanical properties were carefully prepared to substitute for soft rock. The evaluation results show that the method has an intrinsic applicability in helping to make a reasonable trade-off between cost and cutting performance during the cutter selection process.

1. Introduction

Shield tunnel boring machine (TBM) is an advanced tunneling device, commonly employing scrapers and disc cutters to excavate soft rock and soil encountered [1]. As a basic functional unit of the cutterhead, the cutters are installed on a cutterhead using a certain layout and their merit is determined by mechanical and geological parameters (e.g., rock hardness, strength, and abrasiveness) [2, 3]. So it seems that cutter design is an interesting geomechanical synthesis exercise involving a multifactor evaluation.

Currently, most researchers focus on the study of cutting forces and their associated performances such as specific spacing/penetration corresponding to the minimum specific energy based on cutting tests [4, 5]. These analyses provide some insights into performance evaluation of TBM cutters [6]. However, since only a few performance parameters and a limited range of geological conditions are taken into account, some well-designed cutters which perform well under a certain tunneling ground may not satisfy the multiple requirements of some complex environments which contain different or even diametrically opposite geological conditions. There seems to be a lack of an efficient way to provide a systematic evaluation of multiple performances of TBM cutters under different geological conditions [7].

In this context, a novel evaluation method is proposed, which considers a comprehensive list of individual performances at varying geological grounds. To illustrate how the evaluation method is applied to find the optimal cutter, a case study was then given. In this case, the cutting performance of a small-scale disc cutter and two scrapers which were originally designed for excavating soft rock was analyzed and evaluated individually based on linear cutting tests, finite element analyses, and theoretical calculations; three types of concrete specimens with distinct mechanical properties were carefully prepared to substitute for soft rock. Finally, all the performance indexes of the cutters were then systematically analyzed and the overall merits of the cutter design were discussed.

2. Performance Evaluation Principles

2.1. Performance Parameters

Based on linear cutting tests and finite element analyses (FEA), the following performance parameters can be obtained.

2.1.1. Specific Energy (SE)

It is a widely used index for assessing the cutting efficiency of TBM cutters. Unexpected high SE not only suggests that the cutting process is inefficient, but also implies that potential failures such as excessive wear happen [8]. Considering that the rock-breaking process in the rolling direction consumes almost all of the cutting energy, the energy expended in the vertical direction is comparatively negligible [9]. Therefore, SE is then calculated as follows:where SE is expressed in MJ/m3; Fh is the mean value of horizontal cutting force or rolling force measured by the strain gauges as shown in Figure 1, kN; ρr is the rock density, kg/mm3; mr is the mass of rock debris, kg; and lx is the horizontal cutting displacement of TBM cutters, m.

2.1.2. Cutting Coefficient (CC)

The ratio of the horizontal force to the vertical force is expressed as a percentage which can be considered as an indicator of the amount of torque needed for a given amount of thrust; the higher the CC, the higher the torque needed by TBMs [3].

2.1.3. Magnitude of Cutting Vibration

Due to the characteristics of rock and discontinuities, the cutting vibration is a ubiquitous problem, resulting in seal failures, fatigue cracks on cutter tips, and bolt looseness [10]. The magnitude of vibration acceleration reflects the intensity of the external excitation and therefore represents the dynamic performance. In this paper, only vertical vibration acceleration is considered.

2.1.4. Maximum Equivalent Stress, σmax

Structural strength of TBM cutters is another criterion to check whether the cutters can withstand heavy cutting load and to examine whether the stress concentration occurs on the cutter tips. It is hard to directly obtain the stress distribution of the cutters by theoretical calculation. Considering that FEA is widely used in engineering analysis and calculation, we use the finite element analysis software ANSYS to calculate the maximum equivalent stress σmax. Before solving the static FE model in ANSYS, the experimental mean cutting forces are applied on the contact surface of the cutter ring with rock in the form of nodal forces. Meanwhile, uniform radial nodal displacement δmin is applied on the nodes attached to the inner surface of the cutter ring to simulate the interference fit. δmin is set to 0.05 mm.

2.1.5. Wear Life,

Cutter wear incurs the costs of downtime as well as the costs of refurbishing and replacing the cutters [11]. Therefore, it is a critical factor contributing to performance. Based on site surveys, Wijk proposed that the wear life should be approximately inversely proportional to CAI2 and (σcσc)1/2 and proportional to the wear volume of the cutters and the cutting pressure on rock [12]. Incorporating all the assumptions above, the wear life can be calculated bywhere is the maximum allowable tip width of a worn cutter, m; can be easily calculated according to the geometric characteristics of cross-sections of the worn cutter with a given , m3; wear coefficient Σ is set to 2.024 × 1024 Pa2/m; CAI is Cerchar abrasivity indices; σc is uniaxial compressive strength, Pa; and σt is tensile strength, Pa.

2.2. Evaluation Method

Multiple performance parameters and geological conditions would make the evaluation more realistic but also would greatly complicate the evaluation process. To tackle this problem, a systematic evaluation method is proposed based on the concept of parameter profile analysis [13]. A m × n performance data matrix (PDM) (dij) can be obtained which is a schematic representation of a collection of performance parameters Pi (i = 1, 2, …, m) for multiple specimen Sj (j = 1, 2, …, n). PDM can be further converted into the matrix PDM′ in which all data points have upper acceptable limits. For example, if Pm has a lower acceptable limit, the inverse of the data point must have the upper acceptable limits.

The system should be best considered with respect to the limits of performances that may be acceptable, and the best performances that can be expected from the TBM applications. Therefore, upper boundary matrix (UBM) (uij)m×n and margin rate matrix (MRM) (mij)m×n are defined here to represent the upper acceptable limit and the expected best improvement rate of i-th parameter under j-th geological condition, respectively. Both of the matrices can be determined from technical literatures or from the estimations by experienced designers. The character of the system can be assessed by a review of the profile of the performance parameters at different geological conditions with respect to the proximity of actual performances to the unacceptable limits and the best values of the performances. The parameter profile matrix (PPM) is then introduced as follows:

To ensure that the data point in the PPM (Dij) is a nondimensional number within the range 0–10, if Dij > 10, it is set at 10; if Dij < 0, it is set at 0. For each row and column (i.e., for each parameter and geological condition), the mean and standard deviation (SD) are calculated. The SD is a measure of the degree of the dispersion of the data around the mean. A cutter with satisfactory performance should have a low SD and a high mean. The existence of high SD signifies that the cutters will be likely to have significant problematic areas; a high SD for a row indicates a variable performance under different geological conditions in the design for a particular parameter; a high SD for a column indicates that the cutters will have significant problematic performance under that geological condition.

To analyze the performance at a more advanced level, a parameter performance index PPIi and a case performance index CPIj can be defined as

From equations (4) and (5), the indices are calculated by summing the inverse of the data points to attenuate the effect of any particularly low scores being hidden by high scores in other respects, and this is possible when only the mean is calculated. The system may be reviewed as follows:(1)A comparison of PPIs will indicate whether the system performs better with respect to some performances than others(2)A comparison of CPIs will show whether the system performs significantly better at some geological conditions than others

The mean values, CPIs, PPIs, and SDs provide an efficient way to analyze the system from different perspectives. An overall performance index (OPI) is then used to develop the overall objective function. The OPI, which takes the form of a qualitative score, can be established for the system by considering all the performances and all the geological conditions. The OPI function lies in the range of 0–100. Each performance parameter and each geological condition are given a weighting value according to its importance. The OPI can be expressed as follows:where WPi and Wcj are weighting factors in the range of 0–1 reflecting the preference for different parameters and different geological conditions. Weighting factors satisfy the following equations:

3. Case Study

3.1. Experimental Platform and Cutters

The cutting tests were performed on the standard linear cutting machine (LCM) with the size of 3.7  m × 1.7  m × 3 m (see Figure 2(a)) at the State Key Laboratory of High Performance Complex Manufacturing of Central South University. The system is designed for cutter loads up to 440 kN (vertical) and 220 kN (horizontal) with sufficient stiffness to minimize the rig deflections during the tests. A disc cutter (Figure 2(b), numbered as C1) and two scrapers (Figure 2(c), numbered as C1 and C2) were used in cutting tests. C1 is an 8.5″ constant-cross-section disc cutter with 6.5 mm tip width. C2 and C3 have the same tip width 120 mm with different rake angles γ 10°/20° and edge angles α 70°/60°. To reduce costs, the above cutters were made of standard hardened steel.

As the LCM was originally designed for cutting granite by roller cutters such as disc cutters and spherical tooth hob cutters [14], a special square shaft (see Figure 1) was specifically designed to fix C2 and C3 on the saddle by screw blots. As shown in Figure 1, strain gauges were attached on the saddle in certain pattern, ensuring that the cutting forces were measured in three directions precisely (vertical, horizontal or rolling, and side). Vibration signals were also measured by acceleration sensors.

3.2. Specimen Preparation

It is hard to control rock-breaking tests due to the randomness of natural rocks. To overcome this shortcoming, concrete specimens were used to substitute for soft rock in this paper. By strictly controlling concrete curing time and the ratios of fine sand (0–4 mm), cobblestones, commercial cement, and water, three sets of concrete specimens with distinct mechanical properties (referred to as S1, S2, and S3) were separately casted in specimen boxes. During cutting tests, each box can be firmly fixed on the granite base.

Rock samples’ mechanical properties were tested on WHY-200 automatic compression testing machine. CAIs were measured according to Cerchar method ASTM D7625-10 [15]. The average properties and component ratios are listed in Table 1. The ratio of compressive to tensile strength in S1 is close to 23, indicating an anticipated brittle behavior. On the contrary, a typical elastic-plastic behavior would be observed in S3. It also can be seen that S2 with an abundance of quartz-rich sand is expected to be more abrasive, which will intensively decrease the wear life of the cutters [16]. It is worth to note that the sizes of the concrete specimens are large enough (nominally 1072 × 250 × 144 mm) compared with the sizes of the cutters.

3.3. Experimental Scheme

During the tests, the hydraulic system moves three cylinder rams: the two vertical rams force the cutters to penetrate the specimen surface to depths of 8 mm while the other one moves the specimen box horizontally to cut the specimen. The moving direction of the support is away from the viewer (Figure 2(a)). Each cutter has to cut three specimens, respectively. To ensure that each cut is made without the influence of the previous cut, the specimens are only allowed to be used once. During the experiment, the cutting length was kept the same and the cutting force of the hob was recorded in real-time.

4. Results and Discussion

4.1. Performance Analysis

Set P = [SE, CC, , σmax,] and S = [S1, S2, S3]. All the performance results at all the geological conditions in Table 2 are obtained individually and analytically. These data are ready for processing using the proposed evaluation method. Tests also support the above notions. C1 produced more fragmentations in S1 (Figure 3(a)) than in S3. Furthermore, when the penetration depth continues to increase, S3 is fully compressed due to elastic-plastic deformation (Figure 3(c)) and the volume of debits increases slightly. As shown in Figures 3(d) and 3(e), scrapers can fragment soft rock more efficiently.

In Table 2, the maximum stresses σmax of C2 (C3) are overwhelmingly larger than those of C1 when cutting the same specimen. The simplest explanation is that stress concentrations occur around the sharp tips of C2 (C3). Another limitation of the sharp tips is their short wear life (1.99 km) which is only approximately one fourth as much as the shortest wear life of C1 (7.21 km).

The vibration data can help gain a better understanding of the underlying mechanisms with respect to dynamic performance. Frequency-domain analysis shows that TBM cutters are vibrating at low frequency. Vertical vibration amplitude of C1 is appreciably larger in S1 than that in S2 and S3, which suggests that UCS contributes more to vibrational components than the discontinuities. On the contrast, intense vibration can be found when C2 (C3) cut cobblestone-rich specimen S2. This may be explained by the fact that C2 (C3) has higher odds of crashing against these hard cores than C1 due to the larger contact area.

4.2. Systematic Evaluation

The UBM and MRM are listed in Table 3. The PPM can now be drawn up in Table 4.

The nondimensional data in PPM represents the proximity of the calculated performance to the limits of performance. As shown in Table 4, C1 is found to have the lowest rating (1.32) with respect to SE when cutting S3, followed by 1.44 with respect to CC when cutting the same specimen. As discussed before, C1 performs poorly in respect of cutting efficiency while in some other respects, C1 performs well. For example, there are no concerns on the stress level in the structure which is the most conservative aspect of the design (marked 10). Therefore, it is still hard to find the weakest spots in design.

To reveal the character of the cutters more clearly, the means, SDs, and PPIs are listed in Table 5. It can be seen that the maximum stress σmax, and of C1 have high means and low SD; correspondingly, the PPIs for these parameters are high. This means that the design is uniformly good for all specimens with respect to structural strength and dynamic response. However, PPIs of SE and CC are clearly lower than the other performance parameters, which suggests that C1 should be the weakest in these respects. In addition, the corresponding means are low, coupled with relative high SDs, which indicates a variable performance across the three specimens. Similarly, C2 (C3) is designed to be uniformly good for all specimens with respect to , but the weakest spots are the structural strength and wear life.

Profile analysis of PPM is conducted for each row. Similarly, inspection of Table 6 can reveal the toughest geological condition for each cutter quantitatively. As shown in Table 6, C1 performs much better in S1 than in other specimens while the opposite is found for C2 (C3).

As discussed above, an overall analysis across all specimens and across all performance parameters is conducted separately, which enables the designers to quickly find the weakest performance spot and toughest geological condition. It is a powerful tool in product trial and cutter refurbishment to improve the weak spots. For example, according to the above analysis, C1 can be redesigned as a double-edge cutter which is made from the same steel used in the original cutter due to the sufficient structural strength. As the cutting spacing between two edges may induce their lateral cracks to interact, a significant improvement in SE can be expected [3]. Another benefit of the design is that the proposed design will produce more friction and therefore reduce CC owing to its double contact area with the specimens. Similarly, to increase strength and durability, C2 (C3) can be further divided into two parts: a body base and an embedded knife blade. As the blade is made of high-quality alloy steel, a significant improvement in σmax and can be expected. In practice, trade-off between cost and performance must be carefully considered and the above mentioned measures should only be used if necessary.

For evaluating the overall performance, the OPI functions are used to quantitatively estimate the performance levels of the cutters incorporating their expected best performances. Prior to the calculation of OPIs, it is necessary to define the importance levels of the criteria. Specifically, weighting factors of performance parameters can be determined by their contributions to the overall TBM performance such as tunneling cost and advance rate; weighting factors of geological conditions are largely dependent on the corresponding proportions along the tunnel alignment (rock types). For illustration purpose, the OPIs of the three cutters under different sets of weighting factors (simply given by expert scoring method, see Table 7) are illustrated in Figures 4 and 5.

From these figures, it can be seen that the OPIs are determined by both the performances and the weighting factors. Undoubtedly, when high priority is put in σmax and S1 (referred to as Set III-2), the highest OPI (close to 35) and lowest OPI (close to 10) can be found for C1 and C3, respectively (see Figure 4(c)). The huge difference between the two OPIs suggests that C1 has a significant advantage over C3 under Set III-2. By comparison, slight difference can be observed under Set III-4, which suggests both C1 and C1 (C1) can be used under given circumstances. It is also worth to note that the relative position of OPI data points in each figure almost remains the same no matter which set of weighting factors of performance (or specimens) is chosen. For example, in Figure 4, the highest OPI of C1 can always be found under the Set 2, followed by the OPIs under the Set 3, Set 1 and Set 4. The similar rules can be observed in Figure 5.

When the tunneling ground only (or mainly) contains S3-like composition (e.g., Figure 5(d)), undesirable large SE and CC will put C1 at an obvious disadvantage and therefore a relatively low OPI is likely to be obtained in most cases regardless the small fluctuations in weighting factors. In other words, trends reflected in the OPIs support this notion that weighting factors can affect the value of OPIs to some extent; the proposed evaluation method has necessary tolerance of uncertainty in weighting factors. Despite all these, a more applicable strategy for the selection of weighting factors should be fully discussed in the future work.

Based on the above analyses, the performance of the cutters is systematically evaluated with respect to the performance parameters which collectively describe the overall performance. In order to combine these parameters, the results obtained from experiments, FEA, and theoretical calculation are converted into nondimensional scores using a linear relationship based on the actual performance to its performance limit. The core of the above conversion is the proximity of the level at which the cutters will perform with respect to the expected best level and acceptable level of the performance described by two matrixes: UBM and MRM. They should be reasonably given by the designers based on their engineering experience; otherwise, the evaluation could be subjected to errors. However, the introduction of these two matrices is inevitable in a design assessment because the evaluation results would not be meaningful unless the performances are judged against the design criteria.

It is a common practice that detailed engineering analyses might be carried out by several engineers with different specialisms especially for large and complex systems like TBMs. The process proposed in this paper brings together the separate analyses and combines them into a manageable design review procedure, which means that the evaluation method has an intrinsic applicability to evaluate the suitability of a TBM cutterhead on a given project. Particularly, this design synthesis concept provides a framework for formulating the quantifiable portion of a system design on which advanced optimization techniques can be brought to bear. It would be the future work that a computer-aid optimization program should be developed for TBM cutterheads.

5. Conclusions

A novel systematic method has been devised to evaluate the overall performance of TBM cutters with respect to different kinds of performances and geological conditions. This method enables the designers to make a quick selection of proper cutters prior to layout design of the cutterheads.

For a design review exercise, the method aims to identify the “weak spots” in the original design, which could help the designers to make a more targeted redesign for refurbishment.

The merits of the three experimental cutters are discussed by applying the proposed evaluation method. By using the method, a reasonable selection among the cutters could be made quantitatively for a mixed geological condition.

Data Availability

The data to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that there are no conflicts of interest.

Acknowledgments

This project was supported by the National Natural Science Foundation of China (51704256, 11832016, and 51775471), Natural Science Foundation of Hunan Province, China (2020JJ4583 and 2017JJ3292), and Scientific Research Project of Hunan Education Department (19C1756), China. This project was also supported by the Changsha Zhuzhou Xiangtan Landmark Engineering Technology Project (2019XK2303 and 2020GK2014) and Xiangtan Science and Technology Project (ZD-ZD20191007).