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1. Introduction

Harmonic impact drilling technology is an emerging efficient rock-breaking method that is developed by the Centre for Applied Dynamics Research (CADR) at the University of Aberdeen to improve the rate of penetration in hard formation [1, 2]. The technology is realized by applying harmonic impact to the rock combining the appropriate drilling pressure and rotational speed. In particular, when the impact frequency of the system is equal to the natural frequency of the rock, the rock will resonate, which is called the Resonance Enhanced Drilling (RED).

Since the technology was proposed, lots of studies have been done by a number of researchers [3–5]. At present, the major research work is concerned with the following aspects. On the one hand, it focused on the dynamic characteristics of the impact system [6–8]. A variety of dynamic models of drill string were presented to analyze the motion state of drilling system. The authors of [8] undertook the modeling of the vibroimpact drilling system and presented the results of the numerical analysis and comparison between two selected models. The study in [9] proposed and investigated a new method of vibrational energy transfer from high-frequency low-amplitude to low-frequency high-amplitude mechanical vibrations for the purpose of percussive drilling.

On the other hand, a series of experimental tests are conducted indoor [10–12]. The ultrasonic test on artificial sandstones and materials of drill tools is carried out indoor in [13], and the FFT transform method is adopted to obtain rocks’ resonance frequencies. Aiming to evaluate the applicability of RED technology to coring operations, a series of coring experiments on sandstone and granite are carried out on a specially designed vertical laboratory drilling rig and improvements in penetration rates up to 180% compared to conventional coring [14]. By comparison with the rock-breaking effect of conventional drilling, the advantages of harmonic impact drilling technology were verified.

In addition, there were a few researches on the fundamental rock-breaking mechanism of the technology. Li et al. [15, 16] analyzed the rock-breaking mechanism of drill tool under harmonic vibroimpacting both theoretically and experimentally. Based on the principle of least action [17], microvibration equation of rock was introduced. Aspects of impact characteristic parameters [15, 18] and rock mechanics parameters [19, 20] were mainly considered in this part.

The innovation of the paper is the dynamic analysis of percussion drilling system under the harmonic impact which is conducted from both percussion drilling model and numerical simulations, and the drilling effect of the harmonic impact technology is proved.

2. Simplified Model

In order to further analyze the interaction between the drill bit and rock, the rock-breaking model of high-frequency harmonic vibration is simplified, and the motion behavior between the drill bit and rock is analyzed separately. The physical model includes the bit mass system, the component system of impact loading, and the friction slider system representing the rock, which are shown in Figure 1. The mass of the bit is m, the static load exerted on the bit by the exciter is $F_s$, and the dynamic load exerted on the bit is $F_0\cos \mathrm{\Omega }t+\phi$. The distance from the initial position of the bit to the rock surface is G. The rock is simulated by viscoelastic sliding block. The spring with stiffness of k and the damper with damping coefficient of c are used to consider the elastic behavior and damping of the rock, respectively.

[figure omitted; refer to PDF]

When the force $P_c$ applied to the rock surface by the drill bit exceeds the critical force of the slider $P_r$, the slider begins to move downward to simulate drilling. The displacement of the bit is $x_{\text{m}}$, the displacement of the rock surface is $x_t$, and the displacement of the slider is $x_b$.

There are three different motion stages for drill bit in the simplified physical model, and the specific analysis process is as follows.

2.1. The Stage When the Drill Bit Is Not in Contact with the Rock

At this stage, the drill bit is not in contact with the rock surface. According to Newton’s second law, the motion differential equation of the whole system can be expressed as$$\begin{array}{}\text{(1)}& \begin{array}{c}m{\ddot{x}}_m=F_s+F_0\cos \Omega t+\varphi ,\\ {\dot{x}}_b=0.\end{array}\end{array}$$

At this point, the force $P_c$ exerted by the drill on the rock surface is$$\begin{array}{}\text{(2)}& P_c=c{\dot{x}}_t-{\dot{x}}_b+k{x}_t-x_b=0,\end{array}$$where $m$ is the bit weight, kg; ${\ddot{x}}_{\text{m}}$ is the acceleration of the bit, m/s²; $x_t$ is the displacement of the rock surface, m; $x_b$ is the displacement of the slide block, m; G is the distance between the initial position of the bit and the rock surface, m; ${\dot{x}}_{\text{t}}$ is the movement speed of the rock surface, m/s; ${\dot{x}}_b$ is the movement speed of the slide block, m/s; $c$ is the spring damping coefficient, N·m/s; $k$ is the spring stiffness, N/m; $P_c$ is the force exerted by the bit on the rock surface, N; $F_0$ is the amplitude of dynamic excitation force, N; $F_{\text{s}}$ is the static load, N; $\mathrm{\Omega }$ is excitation frequency, rad/s; $\phi$ is phase angle, rad; $t$ is time, s.

2.2. The Stage When the Drill Bit Is in Contact with the Rock without Drilling

At this stage, the drill bit is in contact with the rock surface, but the slider system does not move. Similarly, according to Newton’s second law, the motion differential equation of the whole system is as follows:$$\begin{array}{}\text{(3)}& \begin{array}{c}m{\ddot{x}}_m+c{\dot{x}}_t-{\dot{x}}_b+k{x}_t-x_b=F_s+F_0\cos \Omega t+\varphi ,\\ {\dot{x}}_b=0.\end{array}\end{array}$$

At this point, the relationship between rock surface displacement and drill bit displacement is $x_t=x_m-G$, and the force exerted by the drill bit on the rock surface is$$\begin{array}{}\text{(4)}& k{x}_t-x_b+c{\dot{x}}_t-{\dot{x}}_b-P_r=0,\end{array}$$where $P_r$ is the critical force of the slider, N.

2.3. Drilling into Rock

When the drill bit is in contact with the rock surface and the slider system generates motion, the motion differential equation of the whole system is$$\begin{array}{}\text{(5)}& m{\ddot{x}}_m+c{\dot{x}}_t-{\dot{x}}_b+k{x}_t-x_b=F_s+F_0\cos \Omega t+\varphi .\end{array}$$

At this point, the relation between rock surface displacement and drill bit displacement is $x_t=x_m-G$, and the force exerted by the bit on the rock surface is also shown in equation (4).

3. Analysis of Influencing Factors of the Dynamic Model

The dynamic model of high-frequency harmonic vibration impact drilling is numerically calculated by Matlab software, and the influence of rock stiffness, damping, impact frequency, and other parameters on drilling effect is analyzed.

3.1. Noncontact Stage between Drill and Rock

At this stage, the drill bit is not in contact with the rock; that is, the drill bit does not drill. At this point, the distance between the rock surface and the slide $x_t-x_b$ is constant. Its value is determined by the stiffness of rock $k$ and the damping of rock $c$. Therefore, the displacement curve of rock surface with time is a straight line. As shown in Figure 2, rock 1, rock 2, and rock 3 are sandstone, limestone, and granite, respectively.

[figure omitted; refer to PDF]

As shown in Figure 8, the drill bit is five-blade PDC bit and the rock is limestone. In the model, a constant angular velocity is applied to the rotary table, and a WOB and harmonic dynamic load are exerted on the BHA and drill bit, respectively. In addition, the whole model is constrained in the X direction and the bottom of the rock is fixed with all directions. To make the simulation more accurate, the teeth of the PDC bit and parts of the rock which contact the drill bit are meshed more finely than other parts. The specific drilling parameters and rock characteristics parameters are given in Tables 6 and 7.

Table 6

Drilling parameters.

Table 7

Characteristics parameters of limestone.

4.2. Results and Discussion

In the simulation process, no impact force is exerted in conventional drilling compared with harmonic impact drilling. The following discussion on the simulation results will be carried out from the perspective of axial motion and torsional motion of the drill bit.

4.2.1. Axial Motion

In Figures 9 and 10, the axial drilling characteristics of conventional drilling and harmonic impact drilling are presented. As shown in Figure 9, in both drilling methods, the progression of the drill bit increases in a stepwise form with the increase of time due to the stick-slip effect.

[figure omitted; refer to PDF]

It can be obtained from the simulation results that, under the same drilling conditions, the maximum rate of penetration (ROP) is 39.59 mm/s and the average ROP is 5.58 mm/s in the conventional drilling, which are corresponding to 54.77 mm/s and 8.56 mm/s in the harmonic impact drilling, respectively. It is surprising to note that the average ROP is increased by 46.3%, which obviously reveals that the harmonic impact significantly improves the axial drilling efficiency.

In addition, it can also be got from Figure 10 that the maximum reverse velocity is 15.94 mm/s in the conventional drilling, while that is 12.17 mm/s in the harmonic impact drilling. What is more, the stability of axial ROP of harmonic impact drilling is better than that of conventional drilling. It is intuitive that the harmonic impact alleviates the phenomenon of bit bounce, which further demonstrates that harmonic impact drilling can improve the axial drilling performance and achieve the purpose of increasing ROP.

4.2.2. Torsional Motion

Figures 11 and 12 show the torsional drilling characteristics of conventional drilling and harmonic impact drilling, respectively. As can be seen from Figure 11, compared with the conventional drilling, the rotational angular velocity of the drill bit in the harmonic impact drilling decreases, but the degree is only 3.4%. However, from the perspective of the stability of angular velocity, the standard deviation of angular velocity of conventional drilling is 6.2 rad/s, which is 5.7 rad/s of harmonic impact drilling. This confirms that the angular velocity of drill bit under harmonic vibroimpact is more stable. Furthermore, it is important to note that the stability is mainly reflected in the stickiness stage of the drill bit. It can be observed that not only is the stickiness stage shortened, but also the phenomenon of reverse rotation is alleviated.

[figure omitted; refer to PDF]

Based on the analysis of the angular acceleration in Figure 12, we can also come to similar conclusions that the average angular acceleration is higher and the standard deviation of angular acceleration is lower of harmonic impact drilling compared to those of conventional drilling. The simulation results demonstrate that harmonic impact not only does not reduce the cutting effect of the drill bit but also mitigates its stick-slip problem to some extent, therefore making the cutting performance of the drill bit more stable and efficient.

5. Conclusion

Acknowledgments

This study was supported by the Open Fund of State Key Laboratory of Shale Oil and Gas Enrichment Mechanisms and Effective Development (10010099-19-ZC0607-0046). The authors also would like to acknowledge the preliminary work by Siqi Li.