Friction behaviors in the metal cutting process:state of the art and future perspectives

Material removal in the cutting process is regarded as a friction system with multiple input and output variables.The complexity of the cutting friction system is caused by the extreme conditions existing on the tool–chip and tool–workpiece interfaces.The critical issue is significant to use knowledge of cutting friction behaviors to guide researchers and industrial manufacturing engineers in designing rational cutting processes to reduce tool wear and improve surface quality.This review focuses on the state of the art of research on friction behaviors in cutting procedures as well as future perspectives.First,the cutting friction phenomena under extreme conditions,such as high temperature,large strain/strain rates,sticking–sliding contact states,and diverse cutting conditions are analyzed.Second,the theoretical models of cutting friction behaviors and the application of simulation technology are discussed.Third,the factors that affect friction behaviors are analyzed,including material matching,cutting parameters,lubrication/cooling conditions,micro/nano surface textures,and tool coatings.Then,the consequences of the cutting friction phenomena,including tool wear patterns,tool life,chip formation,and the machined surface are analyzed.Finally,the research limitations and future work for cutting friction behaviors are discussed.This review contributes to the understanding of cutting friction behaviors and the development of high-quality cutting technology.

Friction Behaviors of the Hot Filament Chemical Vapor Deposition Diamond Film under Ambient Air and Water Lubricating Conditions

The friction behavior of the hot filament chemical vapor deposition（HFCVD） diamond film plays a critical role on its applications in mechanical fields and largely depends on the environment. Studies on the tribological properties of HFCVD diamond films coated on Co-cemented tungsten carbide （WC-Co） substrates are rarely reported in available literatures, especially in the water lubricating conditions. In this paper, conventional microcrystalline diamond（MCD） and fine-grained diamond（FGD） films are deposited on WC-Co substrates and their friction properties are evaluated on a reciprocating ball-on-plate tribometer, where they are brought to slide against ball-bearing steel and copper balls in dry and water lubricating conditions. Scanning electron microscopy（SEM）, atomic force microscopy（AFM）, surface profilometer and Raman spectroscopy are adopted to characterize as-deposited diamond films; SEM and energy dispersive X-ray（EDX） are used to investigate the worn region on the surfaces of both counterface balls and diamond films. The research results show that the friction coefficient of HFCVD diamond films always starts with a high initial value, and then gradually transits to a relative stable state. For a given counterface and a sliding condition, the FGD film presents lower stable friction coefficients by 0.02-0.03 than MCD film. The transferred materials adhered on sliding interface are supposed to have predominate effect on the friction behaviors of HFCVD diamond films. Furthermore, the effect of water lubricating on reducing friction coefficient is significant. For a given counterpart, the stable friction coefficients of MCD or FGD films reduce by about 0.07-0.08 while sliding in the water lubricating condition, relative to in dry sliding condition. This study is beneficial for widespread applications of HFCVD diamond coated mechanical components and adopting water lubricating system, replacing ofoil lubricating, in a variety of mechanical processing fields to implement the green production process.

Friction Behavior on Contact Interface of Linear Ultrasonic Motor with Hard Contact Materials

How to improve the efficiency of the linear ultrasonic motor with hard contact materials(HLUSM)or the precision motion stage driven by HLUSM,becomes a hot issue.Analysis and testing of friction behavior on the contact interface of HLUSM is one of the key issues.Under the action of ultrasonic vibration and impact,the friction behavior on contact interface is very complex due to micro-amplitude and high frequency.Moreover,it is difficult to observe and test it.Focusing on the frictional behavior on the interface of HLUSM,a new method,through testing the vibration of the driving tips(scanning vibrometer PSV-400-3D)and the motion of the slider(displacement sensor LK-G30),respectively,is proposed.Then,take the HLUSM as an example,theoretical analyses and experiments are carried out.Theoretical analysis shows that the average speed of the slider should be 600 mm/s when there is no slippage between the stator and slider during the contact process.Experimental results show that the average speed of the slider is about 390mm/s.At the same time,the tangential vibration speed of the driving tip of HLUSM is larger than 600 mm/s.Therefore,there must be slippage between the stator and slider of HLUSM.Further experimental results show that the maximum efficiency is less than 10%.The slippage on the contact interface should be the main reason for the low efficiency of HLUSM.

Microstructure and Internal Friction Behavior of Laser 3D Printed Fe-Based Amorphous Composites

Laser 3D printing,also known as laser additive manufacturing(LAM),is favored for its ability to form bulk metallic glass(BMG)and its composite materials(BMGcs)with freeform geometries.In this work,two different kinds of Fe_(41)Co_(7)Cr_(15)Mo_(14)C_(15)B_(6)Y_(2)amorphous coatings(A and B)were prepared by using LAM technology under air-and water-cooled conditions,respectively;meanwhile,to reduce the cracks generated due to the residual thermal stresses,coating C obtained by air-sweep annealing of B with a low energy-density laser.The morphology and amorphous content and microstructure of the coatings were investigated,the results show many cracks in coating B deposited under water-cooled conditions,and its microstructure shows an amorphous-crystal-nanocrystalline mixed structure.Cracking was suppressed in coating C,obtained by air-sweep annealing based on coating B,but the amorphous content was reduced from 32.6 to 13.4%.And the hardness and corrosion resistance of the coating will increase with the increase in the amorphous content.Finally,the internal friction behavior of a BMGcs was prepared on the basis of the process of sample C is compared with that of as-cast amorphous alloys.The results show that the low temperature internal friction behavior of BMGcs is affected by the defects produced during printing,and the high temperature internal friction behavior is affected by the precipitated hard phase.

Correlation mechanism of friction behavior and topological properties of the contact network during powder compaction

The effect of friction behavior on the compacted density is significant, but the relationship between the topological properties of the contact network and friction behavior during powder compaction remains unclear. Based on the discrete element method (DEM), a DEM model for die compaction was established, and the Hertz contact model was modified into an elastoplastic contact model that was more suitable for metal-powder compaction. The evolution of the topological properties of the contact network and its mechanism during powder compaction was explored using the elastoplastic contact model. The results demonstrate that the friction behavior between the particles is closely related to the topological properties of the contact network. Side wall friction results in smaller clustering coefficient (CC) and excess contact (EC) in the lower region near the side wall. Corresponding to this phenomenon, the upper region near the side wall has more high-stress particles when the major principal stress threshold was considered, and the CC and EC are significantly higher than those in the other regions. This study provides a theoretical basis for improving powder compaction behavior.

Friction Characteristics Between Marine Clay and Construction Materials

Structure-soil interface friction characteristics is of importance to investigate the interaction between engineering structures and soils,especially for offshore structures.The interface friction behavior between marine clay and structural materials with different roughness was studied in this paper by using 3D optical scanning tests,a modified direct shear device and numerical simulation.Relationships between the surface roughness of structures,water content and interface friction angle were presented by model tests.The increase of water contents decreased the interface friction angles.For interfaces with different roughness,the interface friction angles will be smaller than that of the soil when the water content exceeds a certain value.The roughness of the interface and the water content of the soil are mutually coupled to influence the coefficient of friction(COF).This paper proposed a Finite Element Method(FEM)to simulate the interface direct shear tests of structures with different roughness.The surface models with different roughness are established based on the structure data obtained by 3D scanning.The Coupled Eulerian-Lagrangian(CEL)approach was employed to analyse soils sheared by irregular surfaces.The interface behavior for interfaces with different roughness under cyclic shear stresses was analyzed by FEM.

High-temperature friction behavior of amorphous carbon coating in glass molding process

In the glass molding process,the sticking reaction and fatigue wear between the glass and mold hinder the service life and functional application of the mold at the elevated temperature.To improve the chemical inertness and anti-friction properties of the mold,an amorphous carbon coating was synthesized on the tungsten carbide-cobalt(WC–8Co)substrate by magnetron sputtering.The friction behavior between the glass and carbon coating has a significant influence on the functional protection and service life of the mold.Therefore,the glass ring compression tests were conducted to measure the friction coefficient and friction force of the contact interface between the glass and amorphous carbon coating at the high temperature.Meanwhile,the detailed characterization of the amorphous carbon coating was performed to study the microstructure evolution and surface topography of the amorphous carbon coating during glass molding process by scanning electron microscopy(SEM),X-ray photoelectron spectroscopy(XPS),Ramon spectroscopy,and atomic force microscope(AFM).The results showed that the amorphous carbon coating exhibited excellent thermal stability,but weak shear friction strength.The friction coefficient between the glass and coating depended on the temperature.Besides,the service life of the coating was governed by the friction force of the contact interface,processing conditions,and composition diffusion.This work provides a better understanding of the application of carbon coatings in the glass molding.

Friction and Wear Behavior of Modified Layer Prepared on Ti-13Nb-13Zr Alloy by Magnetron Sputtering and Plasma Nitriding

Two kinds nitride modified layers were obtained on Ti-13Nb-13 Zr surface to improve the wear property via magnetron sputtering and plasma nitriding techniques, respectively. The structures of the modified layer and the worn surface after sliding test were characterized using X-ray diffraction（XRD） and scanning electron microscopy（SEM）. The friction and wear behavior of the modified layer against alumina ball was investigated in the absence of lubricant under different loads（1 N and 2 N）. The X-ray diffraction analysis reveals that nitride layer is mainly composed of TiN and Ti2N, while coating film consists of Ti N phase. Friction and wear test indicates that both modified layers can improve the wear resistance compared to untreated Ti-13Nb-13 Zr. Ti N thin film produces very hard surface, but may be easy to cause coating fracture and delamination under high normal load. However, nitride layer exhibits better wear performance. This is attributed to hard compound layer maintained its integrity with the hardened nitrogen diffusion zone during friction and wear process.

An experimental method for measuring friction behaviors of linear rolling guides

Friction behaviors of linear rolling guides(LRGs)are determined by many factors and are crucial for precision positioning.It is difficult to create an expression to describe the friction behaviors exactly and completely.A new experimental method for measuring the friction behaviors of one LRG individually was developed,and linear motor direct drive technology is utilized in the experiment setup.The position signal is acquired by a grating,and the friction of the LRG is deduced by the product of the mass of the moving part and its acceleration.In the experiment,the LRG can move with the friction only,and the friction transition from normal rolling to prerolling stage was detected.The asperities’deformations were utilized to explain it.Hysteresis loops and internal loops were measured.The results indicate the non-local memory of the LRG,and the historical trajectory have an important impact on the friction behaviors of LRGs in the pre-rolling stage.

Investigation of the sliding friction behaviors of locust on slippery plates

The slippery trapping plate in swarm locust control is a method of realizing resource utilization of locust and avoiding pesticide residues in the entironment. Some slippery plates with different material composition or surface characteristic were investigated through the sliding tests of locust on slippery plates, and sliding rubbing behaviors of locusts on the plate were observed by means of CCD video monitoring system. Poor sliding character of silicate glass to locust was verified, which is in accordance with the adhesive effect generated by secretion of locust feet pads on the smooth surface. And also, PVC plastic plate presents a poor sliding character to locusts, because the soft surface of PVC can permit claws of locust feet to engender mechanical interlock on the surface. The zinc plate shows a considerable slippery ratio for locusts because of the appropriate surface characteristic and material property. Photoelectric stimulation for resting locust can promote the movement of locust. Accordingly, the contact form of locust feet and abdomen on slippery plates is changed and contact area is reduced severely, so the sliding effect of locust on slippery plates is strengthened effectively. These results supply a suitable theoretical foundation for manufacturing locust slippery trapping plates and trapping units, and indicate the important role of photoelectric stimulating factors in biotribology.

Deformation behaviors of 21-6-9 stainless steel tube numerical control bending under different friction conditions

For contact dominated numerical control(NC) bending process of tube, the effect of friction on bending deformation behaviors should be focused on to achieve precision bending forming. A three dimensional(3D) elastic-plastic finite element(FE) model of NC bending process was established under ABAQUS/Explicit platform, and its reliability was validated by the experiment. Then, numerical study on bending deformation behaviors under different frictions between tube and various dies was explored from multiple aspects such as wrinkling, wall thickness change and cross section deformation. The results show that the large friction of wiper die-tube reduces the wrinkling wave ratio η and cross section deformation degree ΔD and increases the wall thinning degree Δt. The large friction of mandrel-tube causes large η, Δt and ΔD, and the onset of wrinkling near clamp die. The large friction of pressure die-tube reduces Δt and ΔD, and the friction on this interface has little effect on η. The large friction of bending die-tube reduces η and ΔD, and the friction on this interface has little effect on Δt. The reasonable friction coefficients on wiper die-tube, mandrel-tube, pressure die-tube and bending die-tube of 21-6-9(0Cr21Ni6Mn9N) stainless steel tube in NC bending are 0.05-0.15, 0.05-0.15, 0.25-0.35 and 0.25-0.35, respectively. The results can provide a guideline for applying the friction conditions to establish the robust bending environment for stable and precise bending deformation of tube bending.

Friction and wear behavior of electrodeposited amorphous Fe-Co-W alloy deposits

The microstructures, friction and wear behavior under dry sliding condition of electrodeposited amorphous Fe-Co-W alloy deposits heat treated at different temperatures were studied. A comparative study of hard chrome deposit under the same testing condition was also made. The experimental results show that the hardness and wear resistance of amorphous Fe-Co-W alloy deposits are improved with the increasing of heat treatment temperature, and reach the maximum value at 800 ℃, then decrease above 800 ℃. Under 40 N load, the wear resistance properties of the alloy deposits heat treated at 800 ℃ are superior to those of hard chrome deposit. The main wear mechanisms of amorphous Fe-Co-W alloy deposits heat treated below 600 ℃ are peeling, plastic and flowing deformation; when the deposits are heat treated above 700 ℃, they are plastic and flowing deformation. While the main wear mechanisms of hard chrome are abrasive wear, fatigue and peeling.

Effects of pin geometry on the material flow behavior of friction stir spot welded 2A12 aluminum alloy

A three-dimensional finite volume model was established by the ANSYS FLUENT software to simulate the material flow behavior during the friction stir spot welding （FSSW） process. Effects of the full-threaded pin and the reverse-threaded pin on the material flow behavior were mainly discussed. Results showed that the biggest material flow velocity appeared at the outer edge of the tool shoulder. The velocity value became smaller with the increase of the distance away from the tool surface. In general, material flows downwards along the pin thread when the full-threaded pin is used. Meanwhile, both the materials of the upper and the lower plates flow towards the lap interface along the pin thread when the reverse-threaded pin is used. The numerical simulation results were investigated by experiment, in which 2A12 aluminum alloy was used as the research object. The effective sheet thickness （EST） and stir zone （SZ） width of the joint by the reverse-threaded pin were much bigger than those by the full-threaded pin. Accordingly, cross tension failure load of the joint by the reverse-threaded pin is 23% bigger than the joint by the full-threaded pin.

Computational analysis of linear friction welding process and micromechanical modeling of deformation behavior for medium carbon steel

Finite element simulation of linear friction welding(LFW) medium carbon steel was carried out using the ABAQUS software. A two-dimensional(2D) coupled thermo-mechanical model was established. First, the temperature fields of medium carbon steel during LFW process were investigated. And then, the Mises stress and the 1st, 2nd and 3rd principal stresses fields' evolution of the steel during LFW process were studied. The deformation behavior of LFW carbon steel was analyzed by using micromechanics model based on ABAQUS with Python code. The Lode parameter was expressed using the Mohr stress circle and it was investigated in detail.

Cr_(3)C_(2)/WC的添加对Stellite 12熔覆层耐磨耐蚀性的影响

目的 提高Stellite 12熔覆层的耐磨耐蚀性能。方法将Stellite 12合金粉末与碳化物(Cr_(3)C_(2)、WC)混合,采用激光熔覆技术在H13钢板上制备复合熔覆层。通过超景深显微镜和XRD分析其显微组织和物相,通过显微硬度测试、摩擦磨损试验和电化学腐蚀试验,分别评价熔覆层的硬度、耐磨性和耐蚀性,并通过超景深显微镜对磨痕形貌进行分析。结果添加碳化物后,熔覆层的微观组织以柱状晶和树枝晶为主,物相主要由γ-Co固溶体和碳化物(M23C6、M7C3)组成;Cr_(3)C_(2)的添加使得熔覆层的硬度降低,由610HV0.2降至530HV0.2,但耐磨性得到提高,磨损量由0.45 mm^(3)降至0.33 mm^(3),下降了28%,耐蚀性得到提高,腐蚀电位由-0.385 V增加到-0.264 V,腐蚀电流密度由9.269×10^(-10)A/cm^(2)降至1.496×10^(-10)A/cm^(2),极化电阻由3.982×10^(7)Ω·cm^(2)提升至2.424×10^(8)Ω·cm^(2),提高了1个数量级;WC的添加使其硬度由610HV0.2提高至750HV0.2,磨损深度变浅,磨损量由0.45 mm3降至0.19 mm^(3),下降了43%,但耐腐蚀性有所降低。3种熔覆层的磨损机制主要为磨粒磨损和黏着磨损。结论WC的添加可以有效提高熔覆层的硬度和耐磨性,但耐腐蚀性有所降低;添加Cr_(3)C_(2)后,耐蚀性得到显著提高,耐磨性略微提升,但硬度降低。

基于磁悬浮理论的自适应抗拔摩擦摆隔震支座力学性能研究

为解决摩擦摆隔震支座抗拔能力不足的问题并优化其隔震性能,将传统的摩擦摆支座(FPB)和半主动控制思想相结合,提出一种自适应磁悬浮抗拔摩擦摆隔震支座(AMFPB)。基于磁路理论进行理论分析,推导出U型电磁铁的电磁力公式,以及AMFPB刚度、周期和等效阻尼比计算公式;对U型电磁铁进行位移-电磁力试验分析,建立AMFPB有限元模型,并对不同位移幅值、不同电磁铁匝数和输入电流下支座的滞回特性和抗拔性能进行分析。研究结果表明:U型电磁铁的位移-电磁力试验结果与理论结果吻合度较好,计算得到的AMFPB滞回曲线与数值模拟结果基本相同。AMFPB随滑动位移的增加可调节自身的刚度及耗能,有利于支座位移的控制。

产品关联对中国差异化产品出口影响研究:基于信息摩擦视角

本文运用反映信息摩擦的产品关联关键性指标,并结合社会网络分析方法,讨论了产品关联对中国差异化产品出口的影响效应。研究发现:①较高的产品关联度能够弱化信息摩擦,促进中国差异化产品出口;②在自由分类法下,基于产品关联的全球价值链活动有利于出口产品信息扩散与共享,在保守分类法下,产品分类的差异性将导致信息摩擦对中国出口的影响呈现“产品转移效应”;③在产品关联网络中,中间中心度对中国差异化产品出口更具促进作用,体现了更高的网络资源控制能力、更强的信息传递控制能力、更大的网络枢纽作用等越有利于产品出口;④传统引力模型中的地理距离与反映信息摩擦的产品关联均为影响当前国际贸易的重要因素。

润滑介质及基体对不同厚度PTFE/PI-PAI涂层的摩擦性能

船舶发动机轴瓦在受到炮弹攻击后处于极端工况,造成轴瓦失效破坏。传统的电镀镀层和磁控溅射薄膜因存在高污染、高成本等缺点,目前亟须寻求新的解决方案来提高轴瓦在极端工况下的耐磨性能。针对轴瓦因炮击而处于极端工况,设计了ZrO_(2)填充PTFE/PI-PAI的涂层材料,采用液体喷涂工艺在A370铝合金和CuPb22Sn2.5铜合金基体表面制备三种不同厚度涂层,研究涂层在不同润滑介质下的摩擦学性能。结果表明,涂层的摩擦学性能受到涂层硬度、润滑介质及基体支撑作用影响,涂层的硬度及弹性模量随厚度的增加呈现递减的趋势。涂层越厚,基体的支持作用越小。在油润滑工况下,铜合金基体上涂层摩擦因数及磨损率均小于铝合金,润滑油是涂层摩擦性能最主要影响因素。在海水工况下,涂层主要表现为磨粒磨损,并出现明显的犁沟现象。铜合金基体上涂层的摩擦因数高于铝合金,海水腐蚀和高频往复摩擦带来的冲刷作用是摩擦性能主要影响因素。在干摩擦工况下,涂层以黏着磨损为主。涂层的硬度受到基体支撑的影响,高频往复运动中硬质对磨球与硬质基体夹击软质涂层和接触压力是摩擦性能主要影响因素。通过涂层与合金摩擦因数对比,可知30μm涂层能够大幅度地降低轴瓦材料的摩擦因数,有利于提高船舶发动机轴瓦在极端工况的摩擦学性能。阐明了基体对不同厚度自润滑涂层的支撑机理,分析了涂层在极端工况下受到轰击后的摩擦学性能,确定了船舶发动机轴瓦涂层的最佳设计厚度。

Friction and Wear Performance of Boron Doped, Undoped Microcrystalline and Fine Grained Composite Diamond Films

Chemical vapor deposition （CVD） diamond films have attracted more attentions due to their excellent mechanical properties. Whereas as-fabricated traditional diamond films in the previous studies don＇t have enough adhesion or surface smoothness, which seriously impact their friction and wear performance, and thus limit their applications under extremely harsh conditions. A boron doped, undoped microcrystalline and fine grained composite diamond （BD-UM-FGCD） film is fabricated by a three-step method adopting hot filament CVD （HFCVD） method in the present study, presenting outstanding comprehensive performance, including the good adhesion between the substrate and the underlying boron doped diamond （BDD） layer, the extremely high hardness of the middle undoped microcrystalline diamond （UMCD） layer, as well as the low surface roughness and favorable polished convenience of the surface fine grained diamond （FGD） layer. The friction and wear behavior of this composite film sliding against low-carbon steel and silicon nitride balls are studied on a ball-on-plate rotational friction tester. Besides, its wear rate is further evaluated under a severer condition using an inner-hole polishing apparatus, with low-carbon steel wire as the counterpart. The test results show that the BD-UM-FGCD film performs very small friction coefficient and great friction behavior owing to its high surface smoothness, and meanwhile it also has excellent wear resistance because of the relatively high hardness of the surface FGD film and the extremely high hardness of the middle UMCD film. Moreover, under the industrial conditions for producing low-carbon steel wires, this composite film can sufficiently prolong the working lifetime of the drawing dies and improve their application effects. This research develops a novel composite diamond films owning great comprehensive properties, which have great potentials as protecting coatings on working surfaces of the wear-resistant and anti-frictional components.

超音速火焰喷涂410不锈钢涂层组织结构及摩擦学行为研究

采用超音速火焰喷涂技术制备氧燃比为4.36、4.91及5.51的410不锈钢涂层,利用X射线衍射仪(XRD)、扫描电子显微镜(SEM)和显微硬度仪分析表征涂层微观组织结构及力学性能.研究微观组织结构和粉末沉积特性对涂层在干滑动摩擦条件下磨损性能的影响.结果表明:随着氧燃比的升高,涂层结构变得均匀致密,涂层孔隙率由0.71%下降至0.38%,涂层显微硬度略下降约1%.随着氧燃比的增加,涂层磨损率从17.96×10^(-6) mm^(3)/(N·m)下降至9.35×10^(-6) mm^(3)/(N·m),涂层耐磨性能升高,并且稳定磨损阶段涂层主要磨损机制从分层磨损和磨料磨损转变为氧化磨损和轻微磨料磨损.当氧燃比为5.51时,涂层具有较低的孔隙率和均匀的微观结构,涂层的分层磨损倾向更低.