1.Introduction

Two major types of drillings are commonly used in the mineral,oil and gas,and construction industries:(i)rotary drilling,where a static thrust or weight-on-bit(WOB)is applied to the bit,and(ii)rotary-percussion drilling,where percussive hammer impacts are applied to the bit in addition to a static WOB.It is well known that the rotary drilling performance,as measured by drilling rate-of penetration(ROP),and the nature and rate of bit wear,are strongly influenced by bit motions and bit-rock interaction.This has been studied using roller cone and polycrystalline-diamondcompact(PDC)drag bits,which are widely used for oil and gas drilling.Theoretical models have been developed to study the forces applied to roller cone bits as well as the correlation with ROP and drilling conditions(Biggs and Cheatham,1969;Sheppard and Lesage,1988).Empirical relations have been proposed to correlate the drag forces on a single-cutter PDC bit with rock type,depth-ofcut(DOC)and bit wear state(Glowka,1989).Some researchers have reported on bit-rock interactions through measurement and evaluation of the three modes of drill string vibrations(i.e.axial,lateral and torsional),recognizing that these drill string vibrations are excited by bit-rock interactions(Richard et al.,2004;Reyes,2016).

At the Drilling Technology Laboratory at Memorial University of Newfoundland,several investigations have focused on using bit vibrations to improve rotary drilling performance.One study used compliant elastomers beneath rock specimens to enhance the oscillatory motions generated by bit-rock interaction while drilling with PDC bits,which resulted in improved cutting efficiency and overall drilling ROP(Babapour and Butt,2014).Thereafter,this idea was further developed and incorporated into a drilling tool,called the passive Vibration-Assisted-Rotary-Drilling(pVARD)tool,which demonstrated improved ROP under both laboratory and field drilling conditions(Rana et al.,2015;Xiao et al.,2015).Another study investigated the influence of active vibration on drilling performance for diamond drilling with coring bits and full-face drag bits using an electromagnetic vibrating table to vibrate the rock specimen while drilling.These studies varied both the amplitude and frequency of the vibration applied,and demonstrated that ROP was generally increased at a rate proportional to the amplitude of vibration,regardless of the vibration frequency(Li et al.,2010;Babatunde et al.,2011).

One major challenge for investigating rotary drilling is the difficulty to visualize the bit-rock interaction and bit penetration process.Cutting analysis has been used to evaluate the penetration mechanisms by relating the size and shape of cuttings to the fracturing mechanisms(Reyes et al.,2015;Xiao et al.,2015),keepingin mind the potential in fl uence of the mineral fabric of the rock(Abugharara et al.,2016).Acoustic emission(AE)technology provides an indirect way of studying these fracturing processes,in which AE signals are generated by the fracturing and are remotely recorded.This technology has been frequently reported in the early studies on investigating microcrack nucleation and crack propagation processes in core specimens under standard strength tests in the laboratory(Lockner,1993).In the drilling area,the bit wear states were distinguished by studying frequency contents of AE signals using carbide rotary bits(Sun,1999)and a single-cutter bit(Hardyet al.,1995;Shen et al.,1997),and by studying the amplitude using twist drill bits(Ferrari and Gómez,2015).Energy related parameters of AE signals were commonly used to study the bit penetration mechanisms such as the root mean square(RMS)of amplitude and the AE event energy.Some researchers have reported that the RMS of an AE signal is an effective measure of its magnitude(Jung et al.,1994).For the drilling with an impregnated diamond bit,the dominant bit action consisted of cutting and Friction processes(Most of i,2014),and the processes were investigated by monitoring AE signals.In a diamond coring bit drilling,a variation of RMS levels in AE signals was correlated with varying DOC(Karakus and Perez,2014).In a PDC bit drilling,an average AE energy was calculated to investigate bit penetration mechanisms and drilling performances(Xiao et al.,2015).Related studies at the seismic scale(Brune,1970;Madariaga,1976;Atkinson,1993)have related the frequency content of seismic waves to the length of the generated fractures,with longer fractures generating lower seismic frequencies and vice versa.

Diamond core drilling is the primary form of rotary drilling used for mineral exploration and ore body evaluation.The paper outlines an investigation using AE and drill cuttings characterization to evaluate the penetration mechanisms for drilling with impregnated diamond coring bits while applying passive and active bit vibrations.The experiments comprise a series of DOTs where the WOB is increased in a step-wise manner while maintaining a constant bit vibration condition as provided by compliant specimen mountings and an external vibrating table.These drilling vibration experiments were carried out at the same vibration frequency but with incrementally increasing vibration displacements.AE data were recorded for all of the DOTs to provide information about bit-rock interaction during the DOTs.Based on previous studies,we expected to observe an increase in ROP associated with active vibration.However,these experiments provided further data on the effect of the bit-rock interactions and penetration mechanisms that can influence the ROP.

2.Methodology

2.1.Experimental method

Fig. 1 shows the schematic diagram of the experimental setup for conducting DOTs and monitoring of AEs.A small drilling simulator(SDS)was used to conduct DOTs.With the SDS,a suspended mass provides a known WOB(Khorshidian et al.,2014).A Husqvarna coring bit with the outer diameter of 25.4 mm was mounted to the rig swivel.A constant f l ow rate and pressure of tap water f l ushed the cuttings between the bit and rock away to create space for a new round of penetration.The rotary speed was nominally set as 300 revolutions per minute(RPM)for all DOTs,but this measurement slightly decreased with increasing friction and torque from the increasing WOB(Xiao et al.,2015).However,a detailed calibration of the drilling system showed that the rotary speed was approximately constant for any given value of WOB up to the drilling founder point,where the drilling motor had insufficient torque to turn the bit(Reyes,2016).All DOTs conducted for this investigation were at WOBs less than the founder point.A linear variable differential transformer(LVDT)was used to monitor bit penetration depths that the drill bit actually penetrated,and the depths were measured in unit of mm or m.Cylindrical drilling samples measuring approximately 100 mm in both diameter and length were made from a fine-grained concrete cast using fine aggregate,water and Portland cement.Previous studies conducted using this fine-grained concrete material confirm that it behaves similar for drilling to the low-permeability sedimentary rock with the same unconfined compressive strength(UCS)(Zhang,2017).Table 1 lists the geotechnical properties of this material measured using a standard ASTM strength test(ASTM D7012-14,2014)and a standard ASTM ultrasonic test(ASTM D2845,2008).

3．强化低保资金管理，有效防范资金流失。低保资金要按规定程序运行；坚持“三公开”“两公示”制度，接受群众监督；低保资金专户存储、专户管理，民政部门提出低保资金申请，财政部门审核拨入低保资金专户，民政部门从专户中将低保资金按核定的名单与额度拨入低保对象银行账户。

截至9月4日，山东、河南、河北东堤尿素主流出厂报价已出现小幅探涨。山东地区尿素主流出厂报价涨至1940-1950元/吨，临沂地区尿素接货价已涨至1990-2000元/吨；河北地区尿素主流出厂报价涨至1930-1950元/吨；河南地区尿素主流出厂报价涨至1920-1940元/吨；山西地区尿素主流出厂报价涨至1880-1900元/吨；安徽地区报价暂稳，主流出厂报价维持在1980元/吨的高位；其他地区也基本都是稳中探涨之势，贵州地区尿素主流出厂报价甚至已达到2050元/吨左右的水平。

220 Salsalate alleviates hyperglycemia by inhibiting endoplasmic reticulum stress in high fat diet induced obese mice

Both mean particle size dmand distribution parameter n can be estimated by equation fitting on experimental data.Calculations of the two parameters are commonly done by linear regression of data represented as log[-log(cumulative weight percentage)]versus log(retaining powder sieve size).In this method,36.79%of the cumulative weight corresponds to the theoretical mean particle size calculated using a MATLAB routine(Brezani and Zelenak,2010).Fig. 13 shows three samples of PSD and corresponding linear regression fittings using this routine.Mean particle sizes for the three incremental WOBs are found to be 0.026 mm,0.049 mm and 0.069 mm,respectively.

Fig. 1.Schematic diagram for conducting DOTs using a small drilling simulator at the Memorial University of Newfoundland.A DOT is conducted on a concrete cylinder,which is firmly mounted to the vibration table.The vibration levels L1 and L2 are displacement amplitudes of the surface of vibration table measured by a laser sensor.

Table 1 Geomechanics and ultrasonic properties of the drilling sample material(Rana et al.,2015).

Material UCS(MPa)S-wave velocity(m/s)Concrete 51 34 4423 2448 Young’s modulus(GPa)P-wave velocity(m/s)

Fig. 11 plots the average energy with respect to WOB and ROP.In Fig. 11a,the average energy of AE is elevated with the increase in WOB,when the corresponding ROP increases.Under the same WOB,the average energy is greater with a higher level of vibration(L2＞L1＞Passive).These results indicate that AE average energy is positively correlated with the ROP as shown in Fig. 11b.This phenomenon is consistent with the results obtained by previous research,i.e.the higher RMS of an AE signal correlates with a higher DOC(Karakus and Perez,2014),or a higher AE energy comes from a higher ROP(Xiao et al.,2015).In summary,diamonds cut more aggressively with a higher level of ROP,resulting in a greater magnitude of AE energy from rock cracking.

2.2.Testing scheme

For the DOT experiments,a water f l ow rate of 3.78 L/min and a total of bit-penetration depths of approximately 15 mm were confirmed at each WOB.A group of four increasing WOBs were confirmed:84.1 kg,95.3 kg,106.5 kg and 117.7 kg.In each DOT,the four increasing WOBs were applied on a rock cylinder,and a drilling vibration setting was assigned to this test.Those rock cylinders were cast with the same proportions of materials and their geomechanical properties are shown in Table 1.Table 2 lists the inputs for monitoring AE signals.These configurations were used for the following DOTs.

The first series of DOTs was conducted without active vibration for a range if incrementally increasing WOB.Simultaneously,AE signals were monitored and cuttings were collected,providing data for frequency content and event energy analysis and a particle size distribution(PSD)analysis.The second phase of the experiment consisted of two series of active vibration drillings.All other drilling parameters remained the same with the exception of vibration displacement.The two axial displacement settings had been previously described as L1 and L2(L1＜L2).

3.Data acquisition and processing

For each DOT,drilling related data are obtained,i.e.WOB,bit penetration depth-time,and vibration displacement-time.Synchronized AE signals are recorded as well.

Fig. 8 shows the experimental results demonstrating the relationship between ROP and the corresponding vibration level with respect to WOB for the three drilling settings.

Fig. 4 shows an example of the analysis processes for ROP based on bit-penetration depth-time,and of bit vibration from vibration displacement-time.The bit-penetration depth was measured to be 10 mm approximately when the vibration setting of L1 and the WOB of 95.3 kg were chosen.The bit-penetration depth was determined by moving the average of the time-depth data,resulting in a smooth average depth curve.This curve is quasilinear and the slope of this curve was then taken as the ROP.Bit vibration data were first processed by removing the trends of original vibration displacement.Spectral analysis using a fast Fourier transform(FFT)method was used to study a window of vibration displacement(the black square),indicating a dominant frequency of 60 Hz which is consistent with the working frequency of the vibrating table.The magnitude of vibration displacement,within the linear portion of the bit-penetration depth-time curve,was studied using the RMS method(Eq.(1)),which was an effective parameter for evaluating the vibration magnitude as reported by other researchers(Karakus and Perez,2014).The above data processing was facilitated by a routine in MATLAB.

Active bit vibration was indirectly provided by one external electromagnetic vibrating table for the purpose of studying the effect on ROP(Fig. 1).The vibration was con figured to be 60 Hz with two varying amplitudes:0.044 mm and 0.055 mm at the lowest WOB,referred to as L1 and L2,respectively.A rock cylinder was firmly mounted on the vibrating table surface,thus they vibrated axially under controlled settings.Fig. 2 is a schematic diagram showing the penetration process of a six-segment diamond coring bit(Karakus and Perez,2014)along with the laboratory two segment diamond coring bit.Drilling parameters include WOB and rotary speed,which is equivalently expressed as angular velocityΩ.The drill bit penetrates downwards perpendicular to X-X′in Fig. 2a and a segment moves rightwards from applied to rque-onbit(TOB)in Fig. 2b.DOC is defined as the penetration depth of drill bit per revolution(mm/rev).DOC numerically equals ROP divided by the rotary speed.Based on the indentation mechanism of diamonds,DOC tends to decrease with increasing diamond size under the same drilling conditions of a single diamond.Fig. 2c shows the two-segment diamond coring bit used in this research with an outer diameter of 25.4 mm.The resultant WOB is then comprised of a combination of a static and a varying weight due to periodical vibrations.Vibration displacements of the rock cylinder were measured by a laser sensor,which was attached to the stationary rig frame of the SDS(Fig. 3).

Fig. 2.Schematic view of a diamond coring bit drilling:(a)drilling parameters for a six-segment diamond bit,(b)penetration process of a single segment,and(c)two-segment diamond bit used in this paper.Ωis the angular velocity,R is the radius of a segment,and V is the linear speed of a segment.This is modified after Karakus and Perez(2014).

Fig. 3.Overview of the DOT setup(a)with a concrete cylinder for mounting AE transducers,and(b)the laser sensor attached to the stationary rig frame.Diamond bit of Fig. 2c is used to be here.

Table 2 Inputs for monitoring acoustic emission.

Sampling frequency(MHz)P-wave sensor Gain(dB) Peak-peak input(V)Trigger level(V)10 #4 20 10 0.05

where VRMSis the RMS level of data,T is the time period of waveform,and Viis the instantaneous value.

Fig. 5 shows a sample AE signal with 16,384 points at a sampling frequency of 10 MHz.By an FFT analysis of the whole signal,the resultant frequency spectrum shows a considerable peak frequency of 133 kHz.Fig. 6 shows four waveforms of a single AE event recorded at four sensors.For the four waveform characteristics,peak frequencies and spectral centroids remain approximately the same;whilst the waveform energy is significantly different for the four channels due to the distance to AE sources and coupling issue.In this way,one channel of signals is selected for further analysis.With this method,multiple AE signals were analyzed and similar frequency peaks were found.In this manner,this peak frequency was picked as a means of characterizing the AE signal.In each DOT,fifteen AE signals were randomly selected for spectral analysis and corresponding peak frequencies were further characterized by the arithmetic average peak frequency and the standard deviation.In addition,the spectral centroid of 264 kHz was obtained based on the frequency spectrum at a frequency range of 0-1 MHz.This range was chosen to filter out most of the high frequency noise.The arithmetic average and standard deviation of spectral centroids were calculated from over eighty consecutive AE signals.

对教学技能训练而言，名师示范与新教师亲身体验、导师指导与新教师实际训练、观摩讨论与集体评价相结合，突出工科新教师的主动参与、积极训练、深刻反思、反复强化，促进工科新教师在学中练、在练中思、在思中学，推进“学—练—思—学—练”不断循环往复、螺旋式上升，最终养成工科新教师教学基本技能。

Fig. 4.A sample DOT synchronized with the displacement of the vibrating table(a)at vibration L1 and WOB of 95.3 kg,from which an analysis window of vibration(b)and the corresponding frequency spectrum(c)are obtained.The peak frequency of 60 Hz represents the working frequency of the vibrating table.

Fig. 5.A sample AE signal(a)with its frequency spectrum(b)indicating a peak frequency of 133 kHz and a spectral centroid of 264 kHz at vibration L1 and WOB of 95.3 kg.The spectral centroid is calculated based on a frequency range of 0-1 MHz.

Fig. 6.Four waveforms of a single event recorded by four AE sensors from passive drilling at WOB of 106.5 kg.Each waveform is shown in left panel,and the peak frequency and spectral centroid are shown in right panel.

Fig. 7 shows the event count and the average event energy of AEs recorded during a DOT.Every AE signal was grouped by its triggered time and synchronized with the drilling test.Multiple AE signals were continuously triggered and they were recorded at every 2 s according to the data acquisition system.In this figure,an effective drilling penetration process was marked within the time range of 0-20 s and corresponding AE signals were included for further analysis.By integration of a rectified AE waveform,the event energy was obtained on the time domain based on the method developed by other researchers(e.g.Butt and Calder,1998).In this way,this energy has the unit of volt by second or Vs.It is approximately the same as the area under waveform FFT.At a specific time,average event energy was then calculated by an arithmetic mean method on multiple AE event energies.In an effective drilling time window,e.g.from 0 to 20 s herein,the average event energy was then calculated and taken as the AE energy level for this DOT.

4.Data analysis and interpretation

4.1.Drilling performance and vibration

会计的职能在于反映、监督和帮助决策。财务会计部门作为企业运转的“中枢神经”，要辅助提供采纳科学合理的决策，必须有整体观，站在全局的高度，纵观宏观经济、整个行业动态和发展前景、各利益相关者间的往来联系，同时还要熟悉本行业、本单位业务，维护单位各部门之间的分工合作和有效运转，权衡度量分析利弊，进而帮助管理好整个企业。而人工智能财务系统目前只能覆盖会计、审计的一部分基础工作，在这一方面，人工智能无法取代具备管理实践经验的高端会计人才。

In Fig. 8a,the results show an increase in ROP with increasing WOB.At the same WOB,ROP is positively correlated with vibration level.In particular,under a higher WOB,the differences in ROP between three vibration settings are greater than that under a lower WOB.This indicates that axial bit vibration functions to improve ROP at a higher WOB under these experimental conditions.

4.3.1.Particle size distribution(PSD)

Fig. 7.A sample DOT with synchronized vibration(a)and synchronized AE count and average energy(b)at vibration L1 and WOB of 95.3 kg.The time at 0 shows the start of the DOT.

Fig. 8.An assembly of both ROP(a)and the corresponding vibration level(b)in correlation with WOB.ROP is positively correlated with WOB.

In Fig. 8b,the vibration levels for both vibration settings increase at the beginning due to the decrease of vibrating system compliance with increasing WOB.In this way,the vibrating system vibrates more effectively at the rated vibration setting.Then,the vibration levels decrease slightly with increasing WOB due to the depression of vibration from high WOBs,confirming the results of this system reported by other researchers(e.g.Li,2011).At different WOBs,vibration displacements vary and variations of 10%and 14%are shown for vibration drilling setting L1 and L2,respectively.This indicates a relatively stable change of vibration displacement with respect to WOB.The passive vibrations are not zero due to the existence of compliance of the vibration table.The two active vibration levels are provided here as the first stage of evaluating the drilling performance with respect to the active vibration levels.

4.2.Acoustic emission analysis

Figs.9 and 10 show the frequency distributions in correlation with WOB for the three drilling settings.For every DOT,Fig. 9 shows the peak frequency calculated by the arithmetic average method based on the fifteen peak frequencies.While Fig. 10 shows the spectral centroid with respect to WOB.The results show that the peak frequency decreases with increasing WOB.Research on seismology has shown a reverse relation between a corner frequency to a crack size(Brune,1970;Madariaga,1976;Atkinson,1993).In this manner,the decrease in the peak frequency here indicates an increase in the crack size from a diamond bit penetration process when WOBs are increased.In addition,under the same WOB,a decrease in peak frequency is observed,which indicates an increase in the crack size with the increasing vibration level.This decrease is more apparent at a higher WOB than that at a lower WOB,which confirms that bit vibration functions more efficiently at a higher WOB.

In all of the tests,four Panametrics P-wave sensors were placed symmetrically around a rock cylinder to monitor AEs.Locations of these sensors were set identical in reference to the top surface of this cylinder and the location of the sensors was the same for all of the tests to ensure a confident comparison of AE signals between varying WOBs as well as different drilling settings.These sensors were calibrated with a central frequency of 1.14 MHz,and a working bandwidth range from 0.65 MHz to 1.63 MHz at-6 dB attenuation.Four preamplifiers,manufactured by Physical Acoustics Corporation,were used to amplify AE signals at a 20 dB gain.A GaGe CompuScope 8280 A/D board sampled these analogue signals at a sampling frequency of 10 MHz.The measurement of AE signals was synchronized to the drilling test.

From the previous analyses,a summary is given here based on AE parameters(peak frequency and average energy)in response to WOB.An increase in WOB causes increases in the size of crack and corresponding average energy of AE signals recorded from the diamond bit penetration process.In this way,an elevation of ROP is obtained from increasing WOB.In addition,an increase in vibration levels functions similarly.As a result,bit vibration improves the bit rock interaction conditions thereafter enhances the diamond bit penetration.

4.3.Cutting size distribution

角度环使用的是PID控制器中的PD控制器：当在单位时间内，倒立摆摆杆由一个角度运动到另一个角度时，角速度从零变大再变成零，这里的角速度就可以理解为此次角度与平衡位置的差值和上次角度差值的差值(因为角度差值除以单位时间就是角速度)，这刚好契合PID控制器中微分部分参数的要求。

The analysis of cutting PSD was conducted using two standard particle size analysis methods:sieving analysis for grain sizes greater than 75μm and hydrometer analysis for smaller particles.The sieving analysis involved using different sizes of meshes to retain cutting particles,and the weight percentages of each size of particles were assembled according to ASTM D6913(2009).The hydrometer analysis involved quantitative determination of PSD by sedimentation process using a floating hydrometer following ASTM D422-63(2007).Based on all particle size and corresponding passed weight percentage,the cumulative passed weight percentage-mesh size curve is plotted in normal-logarithmic coordinates,i.e.the PSD chart.

Fig. 9.Peak frequency distribution in correlation with WOB at drilling with settings of passive,vibrations L1 and L2.An arithmetic average of the peak frequencies is obtained based on fifteen events at each WOB.Peak frequency is found to decrease with increasing WOB.

Fig. 10.Spectral centroid with respect to WOB for the three drilling settings.Spectral centroids decrease with increasing WOB.

Fig. 11.Average energy of AEs in positive correlation to(a)WOB and(b)ROP for all DOTs using three settings of passive,vibrations L1 and L2.Bit vibration enhances the AE average energy.

Fig. 12.PSD charts for all DOTs using the three settings,i.e.passive,vibrations L1 and L2.Cutting is coarser when the PSD curve shifts to the right for each drilling setting.

Fig. 12 shows the PSD charts for drilling using three settings.A PSD curve corresponds to a drilling.The charts show that the maximum particle size from the three drillings is less than 1 mm.When a single PSD curve shifts to the right for each drilling setting,the particle size tends to be larger with the increase in WOB which is also correlated with the increasing ROP.This scenario has been reported by other researchers,i.e.a higher DOC causes a higher percentage of coarser cuttings(Hardy et al.,1995).PSD curves are barely distinguishable when the mesh size is over 0.4 mm.This is because a minor portion of cuttings(size over 0.4 mm)was obtained from the overall cuttings for each DOT.

4.3.2.Mean particle size

Mean particle size is commonly used to quantitatively characterize the PSD.In 1933,a PSD function was first proposed from a sieving analysis on powdered coal,known as the Rosin-Rammler(RR)model(Rosin and Rammler,1933),or Rosin-Rammler-Sperling-Bennett(RRSB)model(Merkus,2009).Later,this model is widely used to describe the PSD of powders of various types and sizes,and is specifically suited to representing powders from operations such as grinding,milling,and crushing(Djamarani and Clark,1997).This two-parameter function is described in Eq.(2),from which the mean particle size can be obtained.

where R（d）is the retained weight fraction or cumulative weight percentage(%),d is the particle size or mesh size(μm),dmis the mean particle size(μm),and n is the measure of the spread of particle sizes distribution parameter.

根据国家护理专业发展纲要的指示，护理专业内涵式发展要求建立以生为本的教学模式，要求高职院校充分利用当前的信息科技积极建立教育信息化的教学模式，推动护理专业学生的自主学习、个性化学习，帮助护理专业学生提升自身能力。但是，传统的灌输式教育观念是高职院校护理专业教学中最为常见的教学模式，在教学中的信息化建设水平较低，导致护理专业学生思想固化、自主学习能力退化，严重阻碍了护理专业教育信息化以及学生自主学习模式的发展。

对所有入选患者完善生化检查，详细记录包括一般资料、吸烟史、高血压、糖尿病、LDL、HDL、胆红素和血尿酸水平。其中患者入院后第2天空腹抽取肘静脉血进行生化检验。TBIL、DBIL应用钒酸盐法测定，使用日本和光试剂，在贝克曼AU5800全自动分析仪上检测。血尿酸采用尿激酶过氧化物酶偶联法，试剂盒由宁波天康公司提供。总胆固醇、甘油三酯、LDL、HDL等指标均按标准检测方法进行。

Fig. 14 shows the mean particle sizes for DOTs using the three settings.Mean particle sizes increase with increasing WOB,which corresponds to the visual understanding from the previous PSD charts.Under the same WOB,the mean particle size is increased when the vibration level is elevated.Based on the positive correlation of ROP with the bit vibration level previously reported,it confirms that a higher level of vibration helps the diamond bit cut in a larger depth per revolution and coarser cuttings are obtained.

4.4.Correlation of ROP to AE energy and cutting size

Fig. 13.Demonstration of mean particle sizes for three increasing WOBs using the RR diagram,modified from Brezani and Zelenak(2010).Mean particle size is obtained as the mesh size at 36.79%retained.

Fig. 14.Mean particle size positively correlated with WOB for DOTs using the three settings.Coarser cutting is obtained with the increase in WOB.

The response of cutting size distribution or mean particle size to WOB can be related to the previously described AE parameters.The average energy of AEs shows a positive correlation to the crack size,in terms of ROP,which is positively correlated with cutting size.In this manner,the increase in ROP comes from the increase in the average energy of AEs resulting from larger cracks during the diamond bit penetration process,causing coarser cuttings.

1.3 图像分析与数据测量 扫描结束后，平扫期采用B30 Medium Smooth重组3 mm层厚图像，双能量皮髓交界期使用D30f软组织卷积核重组80 kVp和140 kVp的3 mm层厚图像，并通过双能量后处理软件Liver-VNC对皮髓交界期图像进行处理生成虚拟平扫-碘图图像，测量感兴趣区碘值。由两位CT诊断经验丰富的放射科医师对病灶、周围肾实质等进行测量，记录测量的碘含量。

5.Conclusions

(1)For an increase in WOB and also an increase in vibration level,the ROP is in a positive correlation with AE energy,crack size,cutting size distribution and mean particle size.

(2)Diamond bit penetration mechanism is indirectly characterized by AE parameters,i.e.peak frequency,spectral centroid and average energy.They are successfully correlated with crack size,confirming the results reported by other researchers.

(3)A higher level of bit vibration improves the diamond bit-rock interaction,thus helps a diamond bit cut more aggressively,resulting in a better drilling performance.

Conflicts of interest

The authors wish to confirm that there are no known Conflicts of interest associated with this publication and there has been no significant financial support for this work that could have influenced its outcome.

Acknowledgements

The research was conducted at the Drilling Technology Laboratory of Memorial University of Newfoundland and funded by Atlantic Canada Opportunity Agency(AIF contract number:781-2636-1920044),involving Husky Energy,Suncor Energy and Research and Development Corporation(RDC)of Newfoundland and Labrador.

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