Handbook of Lubrication Episode 1 Part 9 ppt

Wear rates of poly methacrylate and BIS/GMA, unfilled and filled with coupled quartz, when sliding on 180-grit SiC abrasive cloth were all similar in magnitude.36 These results suggest t

MINERAL- AND CERAMIC-FILLED RESINS

Mineral-filled resins have been used in a variety of applications to control the viscosity

of the uncured mixture and the hardness, differential thermal expansion, and isothermal shrinkage of the cured material These applications include dental restorative materials and dielectric materials in a multisegmented switch The dental restorative materials must resist the abrasive action of food and dirt particles trapped between the teeth during mastication, resist the grinding of teeth, and resist the mild abrasives in dentifrices The dielectric material must be capable of being polished by abrasive action so that the smooth surface will not cause excessive wear of the graphite composite brushes sliding over the surface

A study of the polishing of mica-filled epoxy34identified two mechanisms of wear When the abrasive particles were larger than the mica particles, wear occurred by crushing and fracturing the mica particles by the rolling and sliding motion Subsequent abrasive particles removed the fractured mica and the resin surrounding them When the abrasive particles were smaller than the mica particles, wear occurred by erosion of the resin surrounding the mica As the support for the mica gradually wore away, the mica particles were removed

by the polishing motions

The erosive wear mechanism has also been proposed for the wear of dental restorative materials.35These materials were quartz or glass filled BIS/GMA resins Wear data suggest the filler volume fraction and the particle size are the most significant parameters affecting wear resistance Interaction of these two parameters as they affect packing density is also important- Scanning electron micrographs of the worn surfaces confirmed the erosion mech-anism in a simulated tooth-brushing wear test The study showed that an impact sliding wear test gave better correlation with in vivo wear of the composites in rabbits than the simulated tooth brushing

Wear rates of poly (methacrylate) and BIS/GMA, unfilled and filled with coupled quartz, when sliding on 180-grit SiC abrasive cloth were all similar in magnitude.36 These results suggest that the resin fracture properties govern the wear rates The negligible correlation

FIGURE 5 Proportionality between volumetric wear and coefficient of

friction, f (From Moore, D F., in The Wear of Non-Metallic Materials,

Dowson, D., Godet, M., and Taylor, C M., Eds., Mechanical Engineering Publ., London, 1976, 141 With permission.)

of the wear results with hardness of the composites tends to confirm resin wear and erosion around the filler as the wear mechanism

Clinical observations also support the erosion mechanism.37In a study of the wear char-acteristics of five experimental resins38 sliding on SiC, aluminum, and quartz papers, the highest wear was caused by the SiC and the lowest by quartz Tests in which a diamond stylus was slid on the resins showed three failure modes Ductile failure (as evidenced by

a smooth wear track) was found at low loads; brittle failure (surface cracks, chevron-shaped) occurred at intermediate loads Catastrophic failure (gross disruption of the surface) was observed at the highest loads

In summary, wear of mineral-filled epoxies occurs by erosion of the resin around the filler for abrasive particle sizes smaller than the filler For large abrasive particles, stresses are high enough to fracture the resin and filler particles, removing both at a rapid rate

POLYMER SELECTION USING PUBLISHED WEAR DATA

Selection of polymers for wear resistance is usually based on wear data and on measured load and sliding speed at which the wear rate becomes catastrophic The latter data are usually referred to as the PV limit for the polymer, where P is the interface pressure and V

is the sliding velocity.39The PV limit is a measure of the energy input to the sliding interface which is sufficient to cause the polymer to soften or melt This softening results in high wear rates which are unacceptable in most applications

Published wear rate data cannot, however, be used to predict absolute wear rates for applications in which the conditions are different from those used to obtain the data In some circumstances, published data cannot even be used to predict relative wear rates of the polymers in a different application One of the major reasons for the poor predictions of wear based on published data is the strong influence that surface roughness has on wear rate.40 Figure 6 shows that an order of magnitude increase in the Raof a surface can result

in wear rate increases that range from a factor of 3 to 1000 In addition, relative wear rates can completely reverse as the roughness changes For example, at a roughness of 0.1 µm, the wear rate of polyacetal is about one ninth that of polyethylene At roughness of 1.0 µm, the wear rate of polyacetal is about six times that of polyethylene

A second reason why published data may not predict wear performance of polymers is the different wear rates that result from single traversal and multiple traversal tests In the latter, the ability of the polymer to form transfer films on the counterface surface can reduce the wear rates experienced on single traversals over the same surface.40Table 2 shows that the ratio of steady-state wear to single traversal wear can vary widely The polymers with the lower ratios tend to be more ductile than those with the higher ratios

A third reason why wear performance may not be predicted from published data is that different test geometries produce different rankings of polymers In Figure 6 and Table 2, Nylon 6/6 has a lower wear rate than polyacetal for both single-traversal and steady-state wear for a cylinder-on-ring geometry However, Nylon 6/6 is reported to have a higher wear rate than that for polyacetal in steady state sliding in a thrust-washer configuration, 0.2 m/ sec sliding speed, 0.20 µm Raroughness, and an interfacial pressure of 2.8 × 105Pa.41 The general conclusion can be drawn that wear rate data in the literature can be useful

in predicting performance of polymers only if the conditions of the test and the application are very similar

Published PV limits of polymers must also be used with caution in predicting performance

in a given application Often a single number is published for the PV limit The implication

is that any combination of P and V less than the limit will be satisfactory At low velocities, however, the pressure is limited by the flow characteristics of the polymer At low pressures, the velocity is limited by frictional heating which causes softening of the surface layers and

conditions of the application are matched as closely as possible must be performed to measure polymer wear For applications where minimal wear is desired the engineering model for wear can be used Experience with this model has shown that the contact may take larger loads than calculated and still satisfy the zero wear criterion

REFERENCES

1 Tabor, D., The wear of non-metallic materials: a brief review, in The Wear of Non-Metallic Materials,

Dowson, D., Godet, M., and Taylor, C M., Eds., Mechanical Engineering Publ., London, 1976, 3.

2 Tabor, D., Wear, a critical synoplic view, in Wear of Materials — 1977, Glaeser, W A., Ludema, K.

C and Rhee, S K., Eds., American Society of Mechanical Engineers, New York, 1977.

3 Briscoe, B J and Tabor, D., The sliding wear of polymers: a brief review, in Fundamentals of Tribology,

Suh, N P and Saka, N., Bds., MIT Press, Cambridge, Mass., 1980, 733.

4 Ludema, K C., Glaeser, W A., and Rhee, S K., Eds., Wear of Materials — 1979, American Society

of Mechanical Engineers, New York, 1979.

5 Lee, L H., Ed., Advances in Polymer Friction and Wear, Plenum Press, New York, 1974.

6 Buckley, D H., Introductory remarks —friction and wear of polymeric composites, in Advances in Polymer

Friction and Wear, Lee, L H Ed., Plenum Press, New York, 1974, 601.

7 Dowson, D., Challen, J M., Holmes, K., and Atkinson, J R., The influence of counterface roughness

on the wear rate of polyethylene, in The Wear of Non-Metallic Materials, Dowson, D., Godet, M., and

Taylor, C M., Eds., Mechanical Engineering Publ., London, 1976, 99.

8 Eiss, N S., Jr and Warren, J H., The Effect of Surface Finish on the Friction and Wear of PCTFE

Plastic on Mild Steel, Paper No IQ75-125, Society of Manufacturing Engineers, Detroit, Mich., 1975.

FIGURE 7 Experimentally determined values of τmax, at zero wear vs measured values of τ′y for different plastics Dry sliding of 302 stainless steel sphere on platens of plastics for 2000 passes (From Clinton, W C., Ku, T C., and

Schu-macker R A., Wear, 7, 354, 1964 With permission.)

9 Eiss, N S., Jr and Bayraktaroglu, M M., The effect of surface roughness on the wear of low density

polyethylene, ASLE Trans., 23, 269, 1980.

10 Lancaster, J K., Geometrical effect on the wear of polymers and carbons, J Lubr Technol., Trans.

ASME 97, 187, 1975.

11 Ratner, S B., Farberova, I I., Radyerkevich, O V., and Lur’e, E G., Connection between

wear-resistance of plastics and other mechanical properties, in Abrasion of Rubber, James, D S., Ed., MacLaren,

London, 1967, 145.

12 Lancaster, J., Abrasive wear of polymers Wear, 14, 233, 1969.

13 Warren, J H and Eiss, N S., Jr., Depth of penetration as a predictor of the wear of polymers on hard,

rough surfaces, J Lubr Technol., Trans ASME, 100, 92, 1978.

14 Giltrow, J P., A relation between abrasive wear and the cohesive energy of materials, Wear, 15, 71,

1970.

15 Lontz, J F, and Kumnick, M C., Wear studies on moldings of polytetrafluorocthylene resin,

consid-erations of crystailinity and graphite content, ASLF Trans., 16, 276, 1973.

16 Rabinowicz, E., Friction and Wear of Materials, John Wiley & Sons, New York, 1965, 168.

17 Hollander, A.E and Lancaster, J K., An application of topographical analysis to the wear of polymers,

Wear, 25, 155, 1973.

18 Eiss, N S., Jr., Wood, K C., Smyth, K A., and Herold, J H., Model for the transfer of polymers

on hard, rough surfaces, J Lubr Technol., Trans ASME, 101, 212, 1979.

19 Eiss, N S., Jr., Warren, J H., and Quinn, T F J., On the influence of the degree of crystailinity of

PCTFE on its transfer to steel surfaces of different roughnesses, in Wear of Non-Metallic Materials, Dowson,

D., Godet, M., and Taylor, C., Eds., Mechanical Engineering Publ Ltd., London, 1976, 18.

20 Deanin, R D and Patel, L B., Structure, properties, and wear resistance of polyethylene, in Advances

in Polymer Friction and Wear, Lee, L H., Ed., Plenum Press, New York, 1974, 569.

21 Pooley, C M and Tabor, D., Friction and molecular structure: the behavior of some thermoplastics,

Proc R Soc London, Ser A, 329, 251, 1972.

22 Tanaka, K and Uchiyama, Y., Friction, wear, and surface melting of crystalline polymers, in Advances

in Polymer Friction and Wear, Lee, L H., Ed., Plenum Press, New York, 1974, 499.

23 Kar, M K and Bahadur, S., Micromechanism of wear at polymer-metal sliding interface, in Wear of

Materials—1977, Glaeser, W A., Ludema, K C., and Rhee, S K., Eds., American Society of Mechanical

Engineers, New York, 1977, 501.

24 Tanaka, K., Uchiyama, Y., and Toyooka, S., The mechanism of wear of polytetrafluoroethylene Wear,

23, 153, 1973.

25 Suh, N P., The delaminafion theory of wear Wear, 25, 111, 1973.

26 Rabinowicz, E., Friction and Wear of Materials John Wiley & Sons, New York, 1965, 151.

27 Moore, D F., Some observations on the interrelationship of friction and wear in elastomers, in The Wear

of Non-Metallic Materials Dowson, D., Godet, M., and Taylor, C M., Eds., Mechanical Engineering

Publ., London, 1976, 141.

28 Schallamack, A., Abrasion of rubber by a needle, J Polym Sci., 9, 385, 1952.

29 Southern, E and Thomas, A G., Some recent studies in rubber abrasions, in The Wear of Non-Metallic

Materials, Dowson, D., Godet, M., and Taylor, C M., Eds., Mechanical Engineering Publ., London,

1976, 157.

30 Ratner, S B., and Farberova, I I., Mechanical testing of plastics — wear, in Abrasion of Rubber, James,

D S., Ed., MacLaren, London, 1967, 297.

31 Kraghelsky, I V and Nepomnyashaki, E F., Fatigue wear under elastic contact conditions, Wear, 8,

303, 1965.

32 Aharoni, S M., The wear of polymers by roll formation Wear, 25, 309, 1973.

33 Hurricks, P L., The wear and friction of elastomers sliding against paper, in The Wear of Non-Metallic

Materials, Dowson, D., Godet, M., and Taylor, C M., Eds., Mechanical Engineering Publ., London,

1976, 145.

34 Eiss, N S., Jr., Lewis, N E., and Reed, C W., Polishing of mica-filled epoxy, in Wear of Materials

— 1979, Ludema, K C., Glaeser, W A., and Rhee, S K., Eds., American Society of Mechanical

Engineers, New York, 1979, 589.

35 Lee, H L., Orlowshi, J A., Kidd, P D., and Glace, R W., Evaluation of wear resistance of dental

restorative materials, in Advances in Polymer Friction and Wear, Lee, L H., Ed., Plenum Press, New

York, 1974, 705.

36 Wright, K H R and Burton, A W., Wear of dental tissues and restorative materials, in The Wear of

Non-Metallic Materials, Dowson, D., Godet, M., and Taylor, C M., Eds., Mechanical Engineering Publ.,

London, 1976, 116.

37 Kusy, R P and Leinfelder, K F., Pattern of wear in posterior composite restorations, J Dental Res.

56, 544, 1977.

38 Powers, J M., Douglas, W H., and Craig, R C., Wear of dimelhacrytale resins used in denial

composites, in Wear of Materials — 1979, Ludema, K C., Giaeser, W A., and Rhee, S K., Eds.,

American Society of Mechanical Engineers, New York, 1979, 605.

39 Lewis R B., Predicting the wear of sliding plastic surfaces, Mech Eng., 86, 32, 1964.

40 Lancaster, J K., Relationships between the wear of polymers and their mechanical properties, Proc Inst.

Mech Eng., 183(3P), 98, 1969.

41 Theberge, J E., A guide to the design of plastic gears and bearings, Mach Design, 42, 114, 1970.

42 Lancaster, J K., Estimation of the limiting PV relationships for thermoplastic hearing materials, Tribology,

4, 81, 1971.

43 Lancaster, J K., Dry bearings: a survey of materials and factors affecting their performance, Tribology,

6, 219, 1973.

44 Bayer, R G., Clinton, W C., Nelson, C W., and Schumacker, R A., Engineering model for wear,

Wear, 5, 378, 1962.

45 Clinton, W C., Ku, T C., and Schumacker, R A., Extension of the engineering model for wear of

plastics, sintered metals, and platings, Wear, 7, 354, 1964.

WEAR COEFFICIENTS

Ernest Rabinowicz

INTRODUCTION

Other chapters have revealed that wear is extremely complicated For example the tem-perature can rise, thus increasing the thickness or changing the nature of the oxide layer Alternatively, plastic deformation or fatigue can damage the material, increasing its tendency

to wear Thus, prediction of the wear rate to any high degree of accuracy (say ± 10%) has

so far defied all attempts, even in cases where the sliding system is well understood and well controlled

However, the task is much easier when we are content with an estimate of the wear rate within a factor of four or five In this case the exact contributions of some of the complicating factors are less significant and leave the order of magnitude of the wear rate unaffected Wear predictions, even though imperfect, can be used in a number of ways besides estimating the wear rate First, an equation for wear indicates the relative influence of various parameters, such as load, hardness, velocity, surface roughness and grain size, and suggests the change in wear that might result if the sliding system is changed Second, computation

of the wear is also important in failure analysis, or in the study of any worn component of

a system

Quantitative analysis of wear starts with the concept that, while a sliding system may be losing material in more than one way, one mechanism will dominate the overall wear rate This dominant mechanism is generally identified as one of the following:

1 Adhesive wear — considered as ‘mild’ or ‘severe’ depending on the rate of wear and the size of the wear debris In this case wear results from adhesion and pulling out of regions of one sliding surface by the other (see the chapter on Metallic Wear for further details of wear mechanisms)

2 Abrasive wear — results from a hard sharp object, which may be a loose abrasive particle or a sharp projection on one of the sliding surfaces, scratching out a groove

in a sliding surface

3 Corrosive wear — caused by mechanical removal of a surface layer formed by a corrosion process

4 Surface fatigue wear — removal of particles loosened by a growth of surface or subsurface fatigue cracks arising from stress variations dueing continued sliding

ADHESIVE WEAR

This principal form of wear is invariably present when two surfaces slide together, and adhesive wear is predominant in many cases where wear occurs by more than one mechanism Adhesive wear has been investigated most intensely, probably because the same interatomic forces at the interface which cause adhesive wear also cause friction

Although a number of studies have investigated the mechanism accounting for the for-mation of adhesive wear particles1,2,3,4 only one simple quantitative relationship has been developed for predicting the wear rate This is the equation derived by Holm5 and refined

by Archard.1

(1)

Here p represents indentation hardness, i.e., the ratio of load applied to area of indentation produced by plastic yielding, of the softer material being worn Parameter k is a non-dimensional constant, the wear coefficient In Archard’s original derivation with a factor of three in the denominator of Equation 1, the wear coefficient physically represented the probability that a sizeable wear particle was produced during the contact of the two surfaces

at an asperity Data presented in this section are based on Equation 1 (i.e., the wear equation without the factor of three) for simplicity Note that such parameters as surface roughness, grain size, sliding velocity, and apparent pressure do not appear in Equation 1 The wear

is independent of them, except insofar as they influence other parameters (e.g., the distance slid is proportional to velocity)

The indentation hardness is best measured by a Vickers, Knoop, or Brinell hardness test The number given in one of these tests is the hardness in units of kg/mm2, and must be multiplied by 9.8 to convert to N/mm2 The various Rockwell scales are arbitrary Conversion

to N/mm2may be made using Figure 1 The hardness of a material is about 3.2 times the yield stress in uniaxial tension or compression

All terms in the wear equation, except k, are readily available parameters like load or material hardness Thus, the key factor in determining the adhesive wear to be expected in any sliding situation is a knowledge of the only unknown, the wear coefficient k

VALUES OF WEAR COEFFICIENT k

Very few investigations have been carried out with the primary aim of generating wear

FIGURE 1 Diagram to help convert various Rockwell arbitrary hardness numbers into hardness stresses,

p, in units of N/mm 2

coefficient data One experimental study was that of Archard and Hirst6and the results are shown in Table 1 The second7consisted of gathering the few wear coefficient values available from published papers, and this led to the information in Table 2 The utility of these wear coefficients is leading more and more to their use in reporting specific machine element and material test results.8

The two tables represent two different approaches to compiling wear coefficient data Table 1 lists typical data, and then a user must find a value that is representative of his sliding conditions In view of the endless variety of sliding, such a tabulation would have

to be extremely extensive for general use The other approach divides all sliding systems into a limited number of categories, and then gives appropriate wear coefficient data for each category This approach is used in the present chapter

For sliding metals, the two factors which mainly determine the value of the wear coefficient are the degree of lubrication and the metallurgical compatibility as indicated by the mutual solubility The metallurgical compatibility represents the degree of intrinsic attraction of the atoms of the contacting metals for each other Such compatibility is best determined from binary metal phase diagrams, which show the extent of mutual solubility or insolubility in the liquid or solid states

Table 1 WEAR COEFFICIENTS FOR UNLUBRICATED SURFACES Material combination Wear coefficient (k)

Low carbon steel on low carbon steel 70 × 10 − 4 60/40 Brass on tool steel 6 Teflon ® on tool steel 0.25 70/30 Brass on tool steel 1.7 Lucite on tool steel 0.07 Molded bakelite on tool steel 0.024 Silver steel on tool steel 0.6 Beryllium copper on tool steel 0.37 Tool steel on tool steel 1.3 Stellite #1 on tool steel 0.55 Ferrilic stainless steel on tool steel 0.17 Laminated bakelite on tool steel 0.0067 Tungsten carbide on low carbon steel 0.04 Polyethylene on tool steel 0.0013 Tungsten carbide on tungsten carbide 0.01

From Archard, J F and Hirst, W., Proc R Soc London Ser A, 236,

397 1956 With permission.

Table 2 WEAR COEFFICIENTS FOR ADHESIVE WEAR

Metal-on-metal

Metal-on-nonmetal Lubrication Identical Soluble Intermediate Insoluble Nonmetal-on-nonmetal

None 1500 × 10 –6 500 × 10 –6 100 × 10 –6 15 × 10 –6 3 × 10 –6

The compatibility of a large number of metal pairs is shown in Figure 2.9The significance

of the various circles, in terms of metallurgical solubility at room temperature, liquid mis-cibility, metallurgical compatibility, sliding compatibility, and anticipated wear are shown

in Table 3 The general rule is that the blacker the circle, the better the sliding characteristics and the lower the adhesive wear coefficient

FIGURE 2 Compatibility diagram for metal pairs The significance of the various circles is shown in Table 3 Partial circles and blank squares are due to insufficient information.

Table 3 COMPATIBILITY RELATIONSHIPS FOR METALS