Microtopography of Finely Ground Steel Surfaces in Relation to Contact and Wear

Interferometric examination and taper sectioning were used to elucidate the microtopography of the contacting surfaces of a finely ground disk and a conically ended rider. The question of the real area of contact when these surfaces are put together under high pressure is considered. Inspection of the wear track on the disk after a short interval of rubbing, with either white oil or a compounded oil, revealed that visible evidence of true metal-to-metal contact was quite sparse in comparison to the potential real area of contact deduced from microtopographical considerations. The scar on the end of the rider, on the other hand, showed evidence of extensive rubbing, as a consequence of the high ratio of the area of the disk track to the area on the end of the rider. The two rubbing surfaces were in a relatively smooth condition; therefore the wear particles must have been small and sparse. When the rubbing path was reiterated many times, the alteration of the contacting surfaces by previous rubbing affected the course of wear on subsequent rubbing. The effect of the lubricant became apparent at this stage of the wear process.     

Third body effects on friction and wear during fretting of steel contacts

Fretting wear proceeds through particle detachment from the contacting surfaces which, while trapped in the contact zone, can affect the frictional and wear response. Ball-on-flat fretting experiments were carried out between steel specimens under gross slip regime. A transition in the coefficient of friction was linked to a critical contact pressure. The microstructure and chemical composition of the third body evolve with the applied pressure. The evolution of the friction coefficient is strongly dependent on the third body properties. The wear is controlled by the applied load and thus the real contact area within the wear track.     

基于分形理论的滑动摩擦表面接触力学模型

依据分形理论,考虑微凸体变形特征及摩擦作用的影响建立滑动摩擦表面接触力学模型。采用一个三次多项式来表达弹塑性变形微凸体的接触压力与接触面积的关系,从而满足在变形状态转变临界点处的微凸体接触面积与接触压力转化皆是连续和光滑的条件。推导出滑动摩擦表面临界弹性变形微接触面积、临界塑性变形微接触面积、量纲一真实接触面积的数学表达式。理论计算结果表明,表面形貌一定时,真实接触面积随着载荷的增大而增大;载荷一定时,真实接触面积随着特征尺度系数的增大而减小,随着分形维数的增大先增大后减小;当表面较粗糙时,摩擦因数对真实接触面积的影响很小;随着表面光滑程度的增大,摩擦因数对真实接触面积的影响增大,真实接触面积随着摩擦因数的增大而增大,特别是当摩擦因数较大时,真实接触面积增大的幅度也较大。接触力学模型的建立,为研究滑动摩擦表面间的摩擦磨损性能提供了依据。     

铁磁材料摩擦过程中磁化效应机制研究

为探究摩擦过程中磁记忆效应产生机制,采用Bitter粉纹法对摩擦过程中摩擦接触区域的磁畴组织进行原位观测,测量不同摩擦次数及不同摩擦载荷下磨痕表面的磁场变化以及摩擦影响区域内磁畴组织的时效变化。实验结果表明:摩擦过程中磨痕表面的磁场经历剧烈增加、缓慢增加到稳定变化3个阶段;摩擦接触区域内的畴壁在摩擦过程中转向垂直于往复摩擦方向,畴壁厚度和间距增加,畴壁的形态呈现弯曲状,且摩擦载荷为40 N时畴壁的这些变化比载荷为20 N时更加明显;摩擦后的磁畴组织发生时效变化,在静置60天后接触区域内畴壁变化后的状态开始消散,摩擦载荷为40 N时消散程度较20 N时小。     

The tribological characteristics of JS material under lubrication of oil

A material composed of a steel backing, a sintered porous bronze middle layer and a layer of reinforced PTFE, which is named JS material, was prepared. The friction, wear and limiting PV values of this material under dry friction as well as the lubrication of number 20 mechanical oil were studied using a MPV-1500 friction tester. The worn surface of JS material and the transfer film formed on the counterface of carbon steel were investigated using scanning electron microscopy (SEM) and electron probe microanalysis (EPMA). The results show that the friction, wear and limiting PV values of JS material can be greatly improved with the lubrication of oil. The results of SEM and EPMA analyses indicate that, under dry friction conditions, the solid lubricant PTFE and Pb easily transfer to the steel counterface and results in the reduction of friction and wear; while under the lubrication of oil, little transference of PTFE and Pb to the steel surface occurs and very small friction and wear are achieved. Analyses of frictional surfaces also suggest that the Pb filler gets enrichment on the rubbing surfaces, which is beneficial in increasing the adhesion of the transfer film with the steel surface.     

Investigation of the Transition State in the Wear of Polyphenylene Sulfide Sliding Against Steel

The effect of sliding variables, including counterface roughness, sliding speed, and contact pressure, on the run-in state of wear and friction was studied. Sliding was performed in the pin-on-disk configuration with a polyphenylene sulfide (PPS) pin resting on the flat steel counterface. Some experiments were also run to study the effect of air cooling and heating. Optical microscopy and scanning electron microscopy were used to study the shape and size of the wear debris, worn pin surface, and the transfer film formed on steel counterfaces. It was found that friction and wear in the run-in state were significantly affected by the sliding variables studied and their influence was closely related to the development of a transfer film during the run-in state. If the transfer film developed during initial sliding, the coefficient of friction increased and wear rate decreased. The wear rate in the run-in state increased with the increase in initial counterface roughness and there was an optimal counterface roughness of 0.06 m Ra for minimum steady state wear rate. A higher applied load led to a higher wear rate in the run-in state but that was not the case with steady state wear rate.     

Wear residues of aramid fibre formation in friction materials

Abstract

Friction and wear characteristics of aramid fibres in the automotive friction material are investigated using a pad on disc type friction tester. By means of SEM and X-ray analysis, the melting aramid fibre and its residues are detected and observed on the rubbing surfaces and lateral surfaces. The aramid fibres suffer the chemical and physical changes due to severe heating induced during braking. When the temperature of the rubbing surfaces of aramid fibres reaches or exceeds the melting point, the fibres on the surface move in the melting state. The melting particles of aramid fibres act as an interface lubricant. So it does not only lead to good wear resistance of the frictional materials, but also causes the coefficient of friction to reduce. The friction and wear mechanism of aramid fibre is discussed and analysed.     

The influence of thin boundary films on real surface roughness in thin film, mixed EHD contact

The behaviour of thin viscous boundary films in the rough surface rolling–sliding point contact operated under thin film lubrication conditions have been observed by thin film colorimetric interferometry. Changes in film thickness distribution within the lubricated contact between steel ball and glass disc were studies with both mineral base oil and mineral oil formulated with non-functionalized polyalkylmethacrylate (PAMA). Recent studies by other researchers showed that this polymer-containing viscosity index improver exhibits some friction-reducing capabilities even though it forms only very thin boundary films on rubbing surfaces. Results obtained in the current study proved that thin viscous boundary films formed on rubbing surfaces can reduce asperities interactions of rubbing surfaces under very thin film conditions. Even though these boundary films do not separate rubbing surfaces completely, they still can provide some protection of contacting bodies against excessive friction and wear.     

Friction and wear of ceramics

The adhesion, friction, wear and lubricated behaviors of both oxide and non-oxide ceramics are reviewed. Ceramics are examined in contact with themselves, other harder materials and metals. Elastic, plastic and fracture behavior of ceramics in solid state contact is discussed. The contact load necessary to initiate fracture in ceramics is shown to be appreciably reduced with tangential motion. Both friction and wear of ceramics are anisotropic and relate to crystal structure as with metals. Grit size effects in two- and three-body abrasive wear are observed for ceramics. Both free energy of oxide formation and the d valence bond character of metals are related to the friction and wear characteristics for metals in contact with ceramics. Surface contaminants affect friction and adhesive wear. For example, carbon on silicon carbide and chlorine on aluminum oxide reduce friction while oxygen on metal surfaces in contact with ceramics increases friction. Lubrication increases the critical load necessary to initiate fracture of ceramics both in indentation and with sliding or rubbing.     

Modeling of fretting wear evolution in rough circular contacts in partial slip

This paper presents a numerical model that maps the evolution of contact pressure and surface profile of Hertzian rough contacting bodies in fretting wear under partial slip conditions. The model was used to determine the sliding distance of the contacting surface asperities for one cycle of tangential load. The contact pressure and sliding distance were used with Archard's wear law to determine local wear at each surface asperity. Subsequently, the contact surface profile was updated due to wear. The approach developed in this study allows for implementation of simulated and/or measured real rough surfaces and study the effects of various statistical surface properties on fretting wear. The results from this investigation indicate that an elastic–perfectly plastic material model is superior to a completely elastic material model. Surface roughness of even small magnitudes is a major factor in wear calculations and cannot be neglected.     

Acoustic spectrometry as used for the evaluation of tribological systems

A study is presented of tribological metal-polymer systems. Parameter analysis by acoustic emission resulting from external friction was used. The experimental results obtained for metal-polymer friction pairs are dependent on various factors including load, velocity of relative travel, microgeometry of the contacting surfaces, physicomechanical properties of the materials and testing period. The rates of acoustic emission, the total acoustic emission and the magnitude of the frequency emission spectrum were used as informative characteristics concerning friction and wear kinetics. A number of general relations were determined for friction pairs, reflecting the influence of these factors on the acoustic activity of a rubbing contact. A relation was discovered between the mode of wear for polymers and the acoustic emission parameters. An assumption was made concerning the correlation between polymer mass loss by wear and the energy of acoustic emission as based on the model under consideration for failure of a simple contact spot.     

Microscopic asperity contact and deformation of ultrahigh molecular weight polyethylene bearing surfaces

The effect of the roughness and topography of ultrahigh molecular weight polyethylene (UHMWPE) bearing surfaces on the microscopic contact mechanics with a metallic counterface was investigated in the present study. Both simple sinusoidal roughness forms, with a wide range of amplitudes and wavelengths, and real surface topographies, measured before and after wear testing in a simple pin-on-plate machine, were considered in the theoretical analysis. The finite difference method was used to solve the microscopic contact between the rough UHMWPE bearing surface and a smooth hard counterface. The fast Fourier transform (FFT) was used to cope with the large number of mesh points required to represent the surface topography of the UHMWPE bearing surface. It was found that only isolated asperity contacts occurred under physiological loading, and the real contact area was only a small fraction of the nominal contact area. Consequently, the average contact pressure experienced at the articulating surfaces was significantly higher than the nominal contact pressure. Furthermore, it was shown that the majority of asperities on the worn UHMWPE pin were deformed in the elastic region, and consideration of the plastic deformation only resulted in a negligible increase in the predicted asperity contact area. Microscopic asperity contact and deformation mechanisms may play an important role in the understanding of the wear mechanisms of UHMWPE bearing surfaces.     

Characteristics of wear results tested by pin-on-disc at moderate to high speeds

The use of a pin-on-disc configuration for investigating the wear mechanism or behaviour of solid materials is examined carefully since the results of such configurations differ from published data and some existing theories cannot be applied to such a configuration directly. The obvious contradictions include the following. The results between the arrangements of the rotating pin and the stationary pin under the same load and speed are different. The bulk temperatures of the rubbing specimens increase with the duration of testing, which may eventually arrive at a steady state. However, before the wear condition reaches a steady state, it will have continuously varied. Moreover, the friction coefficient increases with sliding speed when the applied load on the rubbing specimens is over certain levels. All these contradictions can be reasonably explained with the accurate prediction of bulk and flash temperatures at the contact area. To this end, this paper provides a more reasonable method for the calculation of temperatures and the real and apparent contact areas.     

The effect of phosphating on the friction and wear properties of grey cast iron

The friction and wear resistance of two commercial manganese phosphate coatings have been evaluated. Grey cast iron wear pins were treated by the two processes and were tested by sliding against a steel disc, under both lubricated and dry sliding wear conditions.Phosphating increases the sliding distance to scuffing as well as the scuffing load, whilst marginally reducing the coefficient of friction. No advantage was found in phosphating dry sliding surfaces.Phosphating reduces the likelihood of adhesive wear in marginal or poorly lubricated sliding couples. The choice of phosphate coating is primarily dependent on the surface finish of the sliding counterface; thin coatings are suitable if the counterface is smooth but thicker coatings are superior against rougher surfaces.     

Transfer film bonding and wear studies on CuS-nylon composite sliding against steel

The tribological behaviour of nylon 11 reinforced with lead sulphide filler was studied. The composite specimens with different filler proportions were made by compression moulding. The friction and wear experiments were run under ambient conditions in a pin-on-disk machine with the composite pin riding on the flat surface of a steel disk. It was found that 35 vol.% PbS-nylon composite had the highest wear resistance. The friction and wear tests were run with this composite at different loads, speeds and counterface roughnesses. The wear rate increased considerably when the load was increased from 19.6 N to 39.2 N and the sliding speed from 1 m/s to 2 m/s, but the effect of these increases on the coefficient of friction was very small. The wear rate also increased abruptly when the surface roughness was increased from 0.11 to 0.3 μm but the coefficient of friction was not affected. It was found that the wear process was dominated by the transfer film that formed on the counterface. The transfer film and the worn surfaces were studied by scanning electron microscopy. XPS analysis indicated chemical bonding between the polymer composite transfer film and the steel counterface.     

Friction behavior of quenched and tempered steel in partial and gross slip conditions in fretting point contact

Tangential traction caused by friction in contacting surfaces is a major factor in fretting fatigue that increases stress levels and leads to a reduction in fatigue life. Friction in fretting contact was studied in partial, mixed and gross slip conditions on quenched and tempered steel. Measurements were made with sphere-on-plane contact geometry for polished and ground surfaces. Friction was evaluated from on-line energy ratio and, after the tests, from wear marks. A maximum friction coefficient of over 1.0 was measured at mixed slip zone with polished surfaces, whereas ground surfaces promote lower values in similar operating conditions. The friction coefficient dependence on load cycles and loading frequency is also presented and briefly discussed. The friction data and understanding thus gained is to be used for evaluation of crack initiation with the numerical fretting fatigue model.     

Effect of testing conditions on friction and wear of a polyetheretherketone-based composite

Friction and wear characteristics of a type of polyetheretherketone (PEEK)- based composite were evaluated under two different loading pressures and sliding speeds (P = 1.0 MPa, V = 1.0 m/s and P=2.0 Mpa, V=3.3 m/s). The material was in contact with steel surfaces of two different roughnesses (Ra=0.15 μm and Ra=0.33 μm). Interface temperature, coefficient offriction, depth wear rate, and specific wear rate of the polymer composite changed considerably with the PV value and the counterface roughness. The interface temperature increased with increasing PV value, whereas the friction coefficient decreased. The depth wear rate at the higher PV value was much higher than that at lower PV. In addition, the rougher counterface resulted in a higher friction coefficient, depth wear rate, and specific wear rate, when the PV value was fixed. The effect of counterface roughness on the specific wear rate at the higher PV value was smaller than that at the lower PV. Further variations in friction and wear with testing conditions are discussed along with the corresponding microscopic observations of the worn polymer surfaces and the polymer transferred counterfaces.     

Metal-PTFE material for dry friction bearings

The results of tribotests of a new sheet metal-PTFE material with steel counterbodies having different hardness are reported. They show that the material has a high wear resistance in dry friction. The hardening of the counterface increases significantly the permissible load on the metal-PTFE block. It is found that compaction conditions and the mode of arrangement of hair-cloth threads relatively to the sliding direction affect the metal-PTFE material wear resistance.     

Acoustic emission method for research and control of friction pairs

One of the new physical methods that provides much information about the processes going on in a friction contact zone in real time is acoustic emission (AE). Basic experimental results of AE in friction are presented and analysed. Using AE signals we can get an indication about the state of the friction processes, about the quality of solid and liquid layers on the contacting surfaces in real time, sometimes about intensity of wear, changing of wear and friction regimes and so on. The influence of sliding velocity, load, roughness and some physical and mechanical properties of the body on the parameters of AE are also given. Some attention to the practical implementation of these techniques for control of capability for work of friction pairs in real conditions are given. Modern methods and devices enable condition monitoring of sliding and rolling bearings.     

Friction and wear of polyphenylene sulfide composites filled with micro and nano CuO particles in water-lubricated sliding

The tribological behavior of polyphenylene sulfide (PPS) composites filled with micro and nano CuO particles in water-lubricated sliding condition were studied. Pin-on-disk sliding tests were performed against a steel counterface of surface roughness 0.09–0.11 μm. The lubrication regimes were established from friction data corresponding to various combinations of loads and sliding speeds. Later experiments were performed using the sliding speed of 0.5 m/s and contact pressure of 1.95 MPa, which corresponded to boundary lubrication regime. Micro CuO particles as the filler were effective in reducing the wear of PPS but nano CuO particles did not reduce wear. The steady state wear rate of PPS-30 vol.% micro CuO composite was about 10% of that of unfilled PPS and the coefficient of friction in this case was the lowest. The examination of the topography of worn pin surfaces of nano CuO-filled PPS by SEM revealed grooving features indicating three-body abrasion. The transfer films formed on the counterfaces during sliding were studied by optical microscopy and AFM. The wear behavior of the composites in water-lubricated sliding is explained using the characteristics of worn pin surfaces and transfer films on the counterface.