chapter 15: friction and wear data bank - ufam -...
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15Friction and
Wear Data Bank
15.1 Introduction15.2 Sources of Data 15.3 Materials Found in Data Bank
Metals for Fluid (Oil) Film Bearings • Porous Metals • Plastics • Carbon–Graphites • Miscellaneous Nonmetallic Materials • Materials under Abrasive Wear
15.4 Data Bank FormatMaterial Data • Tribological Data • Data Field Definitions
15.1 Introduction
Tribology is a critical science that has a key role in U.S. technology and competitiveness. Increasedknowledge in tribology attained through research, both fundamental and applied, can lead to improvedsystem reliability and durability, as well as decreased energy and material losses, throughout industrialtechnology. Transfer of tribology research results into general engineering practice is essential and canbe assisted through the dissemination and use of critical tribological data. Tribology encompasses cross-disciplinary research and practice in materials, lubricants, and design (Zum Gahr, 1987). As a result,tribology research results are published in a number of specialized journals. This fact coupled with thediversity of tribology conditions of interest makes it difficult for researchers and engineers who work indifferent fields to locate pertinent information. As a result, advances in tribology have sometimes onlyslowly been incorporated into engineering practice.
One approach to reduce this problem is the creation of tribological data and information banks. Manyequipment manufacturing companies have taken steps to create proprietary data banks for their own usein design and material selection. In the public sector, the National Institute of Standards and Technologybegan in 1985 to develop a computerized tribology information system that would be widely available(Jahanmir et al., 1988). That system, termed ACTIS, was planned in accordance with recommendationsfrom the international tribology community. The system was constructed to be computer-based andsuitable for PCs generally available at that time. Within the limits of available funding, a total of11 individual modules of code and data were developed and marketed. Recently, seven modules of thesystem, including databases and design codes, have been made available to the public without charge(see Further Information). The data included in this publication are drawn from those databases.
15.2 Sources of Data
Data generation in tribology involves a wide variety of experimental systems. In a compilation of 157different wear test systems used to report data at the ASME Wear of Materials Conferences over the
A. William RuffConsultant
period 1977 to 1985 (Glaeser et al., 1986) found that predominant systems were pin/disk (32%), pin/flat(29%), and block/ring (17%). Since each of these test geometries has different mechanical and thermalcontact characteristics, it should be expected that measured tribological data will reflect those differences.Interlaboratory comparisons in fact show significant differences in wear results using basically similarpin/disk systems (Czichos et al., 1987) and even larger differences using dissimilar pin/disk systems(Almond et al., 1987). There is not yet any known way to adjust data from any test geometry to somereference measurement condition.
Since results from laboratory tribology measurements are determined by the properties and conditionsof the specific test system (Czichos, 1978), it is essential that the conditions used are appropriate to thefinal application intended. This requirement has been well stated (Barwell et al., 1983):
“For … experiment to have meaning, it must reproduce the circumstances surrounding the occurrence ofthe phenomena under study. Otherwise the results … will be irrelevant to the purpose of the investigation.”
Ashby and co-workers (Lim et al., 1987) have gathered friction data and wear rate data from theliterature pertaining to pin/disk test systems involving steel/steel contacts. The results for system frictionare shown in Figure 15.1, plotted vs. sliding velocity. Clearly there is a significant spread of friction valuesat any velocity. A simple functional relationship is difficult to justify using these data, and it is impossibleto determine a single representative friction value. The authors discuss possible reasons for the widevariation.
Similar difficulties were found in handling wear data collected from the literature. The scatter inherentin tribology data has been noted by many authors (Rabinowicz, 1981; Ruff, 1989). Figure 15.2 summarizesfindings reported from a laboratory study of sliding UHMW polyethylene against stainless steel (Wal-bridge et al., 1987). By repeatedly interrupting a long-term test, the investigators were able to follow theprogression of the wear coefficient as a function of time. The statistical distribution of those wear
FIGURE 15.1 Variation in coefficient of friction with sliding velocity for unlubricated steel–steel combinations.
SLIDING VELOCITY v (m/s)
2.010-4 10-2 1 102
1.0
0
CO
EF
FIC
IEN
T O
F F
RIC
TIO
N µ
STEELCOEFFICIENT OF FRICTION µ
The range of possiblevalues for rougheneddisks
rougheneddisks
Mirror-smooth disks
coefficients was found to be a lognormal distribution. In most of the cases, there was significant differencebetween the most frequent value and the mean value. That suggests that descriptions of wear data bymean value and standard deviation analysis, while customary, may not always be suitable. This particularpoint needs to be more widely examined as tribological data are evaluated and added to data banks.
Two specific examples of data gathering and evaluation for quite different tribological situations willbe discussed. Two different modes of wear, mild and severe, are involved.
Example 1. Mild Sliding Wear
Mild wear situations are commonly experienced in service. This mode of damage might be consideredas an extreme upper limit to tolerable behavior in many tribological systems. Ashby and co-workers havepublished wear rate results gathered from the literature on selected material combinations. Figure 15.3shows their findings for pin/disk unlubricated sliding wear of low carbon steel against itself (Lim et al.,1987). In order to simplify the figure, contour lines have been drawn here guided by the actual datavalues that were in the original plot. In this graph the variables, normalized pressure and normalizedvelocity, cover a wide range of 4 decades and 6 decades, respectively, while the wear rates cover 6 decades.This clearly represents a physical situation of extremely large range in design and use conditions. Forexample, in certain regions of the plot, a change by a factor of 2 in pressure or velocity can produce achange by a factor of 10 in wear rate. This may be due to changes in the controlling wear mechanisms,or due to inherent sensitivity of wear to conditions in that region.
In order to examine data from a more systematic, controlled perspective, consider two carefullycontrolled interlaboratory studies that have been reported. The VAMAS studies (Czichos et al., 1987)reported the wear constant for steel sliding against steel, as summarized in Figure 15.4. Results for sixU.S. laboratories are individually indicated along with, separately, the average for the U.S. and for theworld laboratories. The individual number of measurements is indicated in each case. It is seen that whilethe average values for the U.S. and world groups agree very well, there is considerable variation amongthe individual U.S. labs, up to a factor of 6 times in the average values reported.
A similar situation is seen in a second set of interlaboratory data developed by a U.K. effort (Almondet al., 1987) and summarized in Figure 15.5. Both single-pin/disk tests, carried out with conditions similarto the VAMAS tests, and tri-pin/disk tests were done. Looking at the single- pin test results, one sees alarge difference in average wear constant value among the individual labs, up to a factor of 4 times. Thecomparison between the single-pin test average and the tri-pin test average disagrees by a factor of about2 times. The large individual differences in average wear constant shown, in spite of the care taken tocontrol test specimen and test condition uniformity, suggest that both bias and precision of the datamust be substantial concerns in any effort to construct data banks.
FIGURE 15.2 The distribution of calculated wear coefficient values of measured wear loss for UHMW polyethylenesliding against type 316L stainless steel.
Example 2. Severe Abrasive Wear
The second example involves a comparison of laboratory abrasive wear data obtained using two differenttest methods. Figure 15.6 shows a comparison (Moore et al., 1983) between two laboratory methods,pin/abrasive disk sliding, and dry sand abrasion, for a high hardness steel. The data for the roundedOttawa sand follow a 1:1 relation comparing measurements from the two tests. However, the results usingcrushed quartz abrasive deviate significantly from that relationship, up to about 50%. The authorsinterpreted this spread to show the significance of different abrasive shape and composition characteristicson wear.
FIGURE 15.3 Contours of constant wear rate order-of-magnitude values (mm3/m) for steel–steel unlubricatedsliding conditions vs. normalized pressure and velocity. (Adapted from Lim, S.C. and Ashby, M.F. (1987), Wear-mechanism maps, Acta Metallurgica, 35, 1-24.)
FIGURE 15.4 Wear constant results from VAMAS interlaboratory measurements of steel–steel combinations inunlubricated sliding. Each bar is a mean value topped by one standard deviation. The number of individual mea-surements is shown above each bar.
10
10-1
10-4
10-2
102
10-3
10-5
1
SLIDING VELOCITY v (m/s)
NO
RM
AL
IZE
D P
RE
SS
UR
E F~
LOW CARBONSTEEL
WEAR-RATE DATA-MAP
-4
-4
-5
-5
-6
-7
-7
-7
-6
-6
-6
-8
-8
-9
-9 -10
One can conclude from these and other examples that extreme care must be used in selecting testresults for data bank construction, so that substantial bias and variability are not introduced into thedata collection.
15.3 Materials Found in Data Bank
A brief discussion of the material types found in the database, Table 15.1, is in order.
15.3.1 Metals for Fluid (Oil) Film Bearings
This group of metals is primarily composed of alloys with a high content of lead, tin, copper, silver,cadmium, indium, aluminum, or zinc. They are compatible against steel journals and thrust surfaces.Friction and wear data are for dry operation with carbon steel. For dynamic lubricated operation with
FIGURE 15.5 Wear constant results from U.K. interlaboratory measurements of steel–steel combinations in unlu-bricated sliding. Each bar is a mean value topped by one standard deviation. The number of individual measurementsis shown above each bar.
FIGURE 15.6 Comparison of relative wear resistances between two abrasion test methods using two types of abrasive.
the load supported on a full oil film, the coefficient of friction commonly lies in the 0.001 range and isdetermined by characteristics of the oil film rather than by the bearing material. With a boundary film,both dynamic friction and wear rates will attain intermediate levels between dry and full oil film values.
The softest material capable of meeting the load and temperature requirements is the common choicefor optimum embedding of foreign particles and tolerating misalignment. Even where fatigue loadcapacity is inadequate with a soft material such as babbitt, the material can be used when it is appliedas a thin layer on a backing of either steel or a stronger bearing material. Note carefully the conditionsused when the data were obtained since most materials are sensitive to changes in conditions.
15.3.2 Porous Metals
These materials are employed extensively in boundary lubricated service for operation within the tabu-lated load, speed, and temperature limits while using the oil supply self-contained within the pores. Whilea PV limit of 1.75 MPa m/s (50,000 psi ft/min) is commonly quoted for use of porous metals, conservativevalues should again be held to 10 to 20% of that limit for long-time service. A PV limit of 0.35 MPa m/s(10,000 psi ft/min) is usually suggested for application of porous metals in thrust bearing applications.
Operating life at the 135°C (275°F) temperature limit given for porous bearing materials will reflectprimarily the oxidation life of the oil impregnating the pores. Much longer life is possible in the 82°C(180°F) range and at even lower temperatures. With continuous feed of oil, porous metals can be usedas fluid (oil) film bearing materials in a wide variety of higher speed and higher load applications. Notecarefully the conditions used when the data were obtained since most materials are sensitive to changesin conditions.
15.3.3 Plastics
Plastic materials are used for dry (unlubricated) or boundary lubricated, slow speed sliding and inter-mittent operation within the tabulated limits of temperature, P, V, and PV values, where P is unit loadingon the projected bearing area in N/m2, V is surface velocity in m/s, and their product PV gives somemeasure of the temperature rise and wear severity for the contact. For acceptable wear performance inlong-term operation, PV values should be held to about 10 to 20% of the maximum PV value listed,which is for short-time running under a most severe condition. The limiting PV given here was usuallydetermined at approximately V = 0.5 m/s (100 ft./min.) in a short-time laboratory bench test. TabulatedP, V, and PV limits are either for dry operation on steel or for operation with the lubricants originallyincorporated (where possible) in the plastic.
With a supplementary supply of lubrication, much more demanding requirements may be accommo-dated. Friction and wear data for the plastics are for sliding against carbon steel surfaces. Manufacturerscan often supply further guidelines for running against aluminum or various plastics. Note carefully theconditions used when the data were obtained, since most materials are sensitive to changes in conditions.
15.3.4 Carbon–Graphites
These materials are widely used for dry operation at high temperature, and also for bearings and sealsrunning with low-viscosity fluids such as water, solvents, and fuels; such fluids are inadequate forlubrication of fluid (oil) film bearing metals. These hard and brittle carbon–graphites require hardenedmating surfaces and tolerate dirt contamination poorly. P, V, and PV data are given for application ofcarbon–graphites in dry operation.
When used with water, fuels, solvents, and many process fluids, the carbon–graphites are excellentfluid-film bearing materials. In such cases, operating limits are commonly much higher than those givenhere, and performance characteristics depend largely on the nature of the fluid film involved in thebearing. Note carefully the conditions used when the data were obtained, since most materials are sensitiveto changes in conditions.
15.3.5 Miscellaneous Nonmetallic Materials
Almost all materials used in the construction of mechanical systems have been employed at some timeas bearing surfaces. Included are examples of the growing group of ceramics and composites which finduse in special applications and as high temperature sliding surfaces. Also included in this group are rubberand wood, which find use with water, slurries, and a variety of low-viscosity liquids. Note carefully theconditions used when the data were obtained since most materials are sensitive to changes in conditions,particularly test pressure and load values for ceramics.
15.3.6 Materials under Abrasive Wear
Abrasive wear data were obtained from laboratory tests using the dry sand/rubber wheel abrasion testas described in ASTM standard G-65. The tests involved abrading a specimen with rounded silica sandof controlled size. The abrasive was introduced between the specimen and a rotating wheel with a rubberrim of specified material. The specimen was pressed against the rotating wheel by a specified normalforce. A controlled stream of abrasive was fed by gravity into the contact region. The wear mode is usuallyreferred to in the literature as low stress, scratching, three-body abrasion.
The data were obtained in a series of interlaboratory tests using the particular conditions given. Thetest conditions used were carefully chosen to provide uniform and reproducible wear. The test methodhas been used to provide relative rankings of materials to wear. In some reported cases a good correlationhas been found between actual abrasive wear performance in service and that measured using this test.However, the severity of abrasive wear will depend on the particulars of abrasive size and shape, and onthe system parameters of load and environment. Note carefully the conditions used when the data wereobtained, since most materials are sensitive to changes in conditions.
15.4 Data Bank Format
The database, Table 15.1, contains data records of two types: materials data and tribological data.
15.4.1 Material Data
These records contain properties data (composition, processing, physical, mechanical) on a group ofmaterials frequently used in tribological applications. Since the materials are used in a variety of differenttribological applications, specific tribological performance data are not given for records of this type.
15.4.2 Tribological Data
These records contain critically evaluated tribological data for a group of materials measured underspecific tribological use or test conditions. The counterface material, the contact environment, and otherparameters associated with the data are specified to the extent that such information was available in theoriginal report. Blank spaces in the data records indicate data not available. Note carefully the conditionsused when the data were obtained, since most materials are sensitive to changes in conditions. Note thatthe materials data in records of this type may not be complete in all cases because they depend on theoriginal source.
15.4.3 Data Field Definitions
The definitions, given here in alphabetical order, in most cases follow ASTM definitions.
Class: A major material class, e.g., metal, ceramic, polymer, etc.Common name: A name frequently given to a particular material, e.g., nylon.Component name: The set of components (elements) present, in order present.Component weight percent: The weight percent of each component (element) in order.
Contact environment: Terms describing the local environment at the contact, e.g., atmosphere, lubricant, abrasive, etc.
Contact geometry: Terms describing the geometry such as pin/disk, etc.Counterface description: Further identification of the counterface.Counterface material: Identification of the opposing surface material, e.g., rubber, steel.Data source: Source of data for this record (consult data sources at end of table).Density: Mass per unit volume, in kilograms per cubic meter.Distance: Sliding distance used in the test, in meters.Expansion coefficient: Increase in dimensions of a body due to change in temperature, in
micrometers per meter per degree C.Form: The material form, e.g., rod, sheet, cast, etc.Fracture toughness
(Mode I, plane strain):Resistance to extension of a crack, given here by KIC, the critical stress
intensity factor for plane strain, linear–elastic conditions, in MPa m1/2.Friction coefficient: Dimensionless ratio of the force resisting motion to the normal force
pressing two moving bodies together.Grade: Designation given a material by a manufacturer.Hardness: Resistance of a material to indentation. The usual methods for hardness
determinations include Rockwell C, Vickers, etc.Heat capacity: Amount of heat necessary to change the temperature of unit mass by one
degree, in kilojoules per kilogram per degree C.Load: Normal contact load used in the test, in Newtons.Maximum operating
temperature:Maximum permitted contact temperature, in degrees C.
Maximum pressure: Maximum permitted contact pressure, in MPa.Maximum velocity: The maximum permitted sliding velocity, in m/s.Melting point: Temperature at which a solid changes to liquid state at one standard
atmosphere, in degrees C.P(ressure) V(elocity)
limit:Maximum permitted value of the product contact pressure times sliding
velocity, in MPa m/s.Principal component: The principal component (element) designation.Processing conditions: Specific process conditions used, e.g., 200°C temperature.Processing and treatment: A descriptive phrase on the process method, e.g., cast.Resistivity: Electrical resistance measured between opposite faces of a centimeter cube
of material, in units of micro-ohm cm.Second component: The second component (element) present.Specification: A precise statement of a set of requirements to be satisfied by a material,
promulgated by an organization, e.g., ASTM-###, SAE-###, etc.Specimen shape: The shape of the test specimen, e.g., block, pin.Standard test: Test designation, i.e., ASTM, SAE, etc.Sub-class: Subdivisions of a class, e.g., ferrous, boride, etc.Temperature: Test temperature, in degrees C.Tensile strength: Maximum amount of tensile load per unit original cross-section area that
a material attains when tested to rupture, in MPa.Thermal conductivity: Time rate of steady heat flow through unit area per unit temperature
gradient, in watts per meter per degree C.Velocity: Relative speed of motion between the two contacting surfaces, in m/s.Wear coefficient: Dimensionless coefficient calculated by the relationship: (wear
volume)∗(hardness)/(load)/(sliding distance).Wear constant: Volume rate of material removal per unit sliding distance per unit load, in
cubic millimeters per Newton-millimeter.Wear rate: Volume rate of material removal per unit sliding distance, in cubic
millimeters per meter.
References
Almond, E.A. and Gee, M.G. (1987), Results from a U.K. interlaboratory project on dry sliding wear,Wear, 120, 101-116.
Barwell, F.T. and Jones, M.H. (1983), Role of laboratory test machines, in Industrial Tribology, Jones,M.H. and Scott, D. (Eds.), Elsevier, NY.
Czichos, H. (1978), Tribology: A Systems Approach to the Science and Technology of Friction, Lubrication,and Wear, Elsevier, NY.
Czichos, H., Becker, S., and Lexow, J. (1987), Multilaboratory tribotesting: results from the VAMASprogram on wear test methods, Wear, 114, 109-130.
Glaeser, W. and Ruff, A.W. (1986), private communication.Jahanmir, S., Ruff, A.W., and Hsu, S.M. (1988), A computerized tribology information system, in Pro-
ceedings ASM Conference on Engineered Materials for Advanced Friction and Wear Applications, ASMInternational, OH, 243-247.
Lim, S.C. and Ashby, M.F. (1987), Wear-mechanism maps, Acta Metallurgica, 35, 1-24.Moore, M.A. and Swanson, P.A. (1983), The effect of particle shape on abrasive wear: a comparison of
theory and experiment, in Proceedings of Wear of Materials Conference — 1983, American Societyof Mechanical Engineers, NY, 1-11.
Peterson, M.B. and Winer, W.O. (1980) (Eds.), Wear Control Handbook, American Society of MechanicalEngineers, NY.
Rabinowicz, E. (1981), The wear coefficient — magnitude, scatter, uses, Transactions of the AmericanSociety of Mechanical Engineers, 103, 188-194.
Ruff, A.W. (1989), Comparison of standard test methods for non-lubricated sliding wear, in Proceedingsof Wear of Materials Conference — 1989, American Society of Mechanical Engineers, NY, 717-721.
Walbridge, N.C. and Dowson, D. (1987), Distribution of wear rate data and a statistical approach tosliding wear theory, in Proceedings of Wear of Materials Conference — 1987, American Society ofMechanical Engineers, NY, 101-110.
Zum Gahr, K.-H. (1987), Microstructure and Wear of Materials, Elsevier, NY.
For Further Information
Free copies of the PC-based code and database modules developed for the ACTIS system are availableby contacting: NIST Office of Standard Reference Data, North Building, Gaithersburg, MD 20899.
A thorough description of the development process that led to the ACTIS system is found in thereference of Jahanmir et al., 1988.
Good, accessible sources of tribological data include Wear Control Handbook (Peterson, M. B. andWiner, W. O. (1980), Eds., American Society of Mechanical Engineers, NY); ASM Handbook — Friction,Lubrication, and Wear Technology, Vol. 18, (Blau, P. J. (1998), Ed., ASM International), and Wear ofMaterials Conference Proceedings, 1977–1999 (published biannually by ASME, NY, and Elsevier, NY).
Wear type: Five possible types are considered: abrasive, adhesive, fatigue, fretting, or lubricated, defined as: (1) abrasive — wear being caused by the action of hard particles or protuberances between the contacting surfaces; (2) adhesive — wear caused by surface interactions usually involving deformation; (3) fatigue — wear due to time-dependent, accumulative fatigue processes at or beneath the contacting surfaces; (4) fretting — wear under oscillating conditions at small sliding amplitudes; (5) lubricated — wear under conditions in which a lubricant is present.
Young’s modulus: Ratio of tensile or compressive stress to corresponding strain below the proportional limit of the material, in MPa.
TABLE 15.1 Tribo-Materials Database (Part A)
NUMBER COMMON NAME CLASS SUBCLASSPRINCIPAL
COMPONENTSECOND
COMPONENT GRADE
1 TITANIUM DIBORIDE CERAMIC BORIDE TIB2
2 BORON CARBIDE CERAMIC CARBIDE B4C
3 CHROMIUM CARBIDE CERAMIC CARBIDE CR3C2
4 SILICON CARBIDE CERAMIC CARBIDE SIC
5 TITANIUM CARBIDE CERAMIC CARBIDE TIC
6 TITANUM CARBIDE CERAMIC CARBIDE TIC HOT PRESSED
7 TUNGSTEN CARBIDE CERAMIC CARBIDE WC K 162B
8 TUNGSTEN CARBIDE CERAMIC CARBIDE WC
9 CARBON CERAMIC CARBON C 2690
10 CARBON CERAMIC CARBON C AG P-5AG
11 CARBON CERAMIC CARBON C S-95
12 CARBON CERAMIC CARBON C T-0054
13 CARBON CERAMIC CARBON C P-9
14 CARBON CERAMIC CARBON C G-1
15 CARBON CERAMIC CARBON C P-03
16 CARBON CERAMIC CARBON C P-2W
17 CARBON CERAMIC CARBON C P-5
18 CARBON GRAPHITE CERAMIC CARBON C
19 CARBON GRAPHITE-BABBITT CERAMIC CARBON C P-15
20 CARBON GRAPHITE-COPPER CERAMIC CARBON C CU
21 CARBON GRAPHITE-GLASS CERAMIC CARBON C SIO2
22 CARBON GRAPHITE-LITHIUM FLUORIDE CERAMIC CARBON C LIF
23 CARBON GRAPHITE-RESIN CERAMIC CARBON C
24 CARBON GRAPHITE-SILVER CERAMIC CARBON C AG
25 GRAPHITE CERAMIC CARBON C
26 QUARTZ GLASS CERAMIC GLASS SIO2
27 SODA GLASS CERAMIC GLASS SIO2
28 SILICON NITRIDE CERAMIC NITRIDE SI3N4
29 TITANIUM NITRIDE CERAMIC NITRIDE TIN
30 ALUMINUM OXIDE CERAMIC OXIDE AL2O3
31 ALUMINUM OXIDE – TITANIUM OXIDE CERAMIC OXIDE AL2O3 TIO2 SPK SN80
32 BERYLLIUM OXIDE CERAMIC OXIDE BEO
33 PARTIALLY STABILIZED ZIRCONIA CERAMIC OXIDE ZRO2 Y2O3 TZ3Y
34 PARTIALLY STABILIZED ZIRCONIA CERAMIC OXIDE ZRO2 1027
35 PARTIALLY STABILIZED ZIRCONIA CERAMIC OXIDE ZRO2 MGO MS
36 PARTIALLY STABILIZED ZIRCONIA CERAMIC OXIDE ZRO2 2016
37 PARTIALLY STABILIZED ZIRCONIA CERAMIC OXIDE ZRO2 Y2O3 Z191
38 SILICON DIOXIDE CERAMIC OXIDE SIO2
39 TITANIUM DIOXIDE CERAMIC OXIDE TIO2
40 WOOD/OIL IMPREGNATED COMPOSITE CELLULOSE WOOD OIL
41 MOLYBDENUM DISULFIDE COMPOSITE COMPOSITE COMPOSITE MOS2 TA PM-103
42 DU (BRONZE/PTFE) COMPOSITE METAL MATRIX CU PTFE
43 STEEL/TiC COMPOSITE METAL MATRIX FE TiC H-46
44 TUNGSTEN CARBIDE – COBALT COMPOSITE METAL MATRIX WC CO K-714
45 TUNGSTEN CARBIDE – COBALT COMPOSITE METAL MATRIX WC CO
46 CAST IRON METAL FERROUS FE NI NI-RESIST 1
47 CAST IRON METAL FERROUS FE CR NI-HARD 4
48 CAST IRON METAL FERROUS FE SI DURIRON
49 CAST IRON METAL FERROUS FE NI NI-HARD
50 CAST IRON METAL FERROUS FE CR HC250
51 CAST IRON METAL FERROUS FE C MEEHANITE
52 CAST IRON, OIL-FILLED METAL FERROUS FE C
53 IRON METAL FERROUS FE
54 IRON-COPPER, OIL-FILLED METAL FERROUS FE CU
55 IRON-COPPER, OIL-FILLED METAL FERROUS FE CU
56 IRON, OIL-FILLED METAL FERROUS FE
57 MILD STEEL METAL FERROUS FE C
58 STAINLESS STEEL METAL FERROUS FE CR 440CM
59 STAINLESS STEEL METAL FERROUS FE CR 304HN
60 STAINLESS STEEL METAL FERROUS FE CR 316
61 STAINLESS STEEL METAL FERROUS FE CR 440C
62 STAINLESS STEEL METAL FERROUS FE CR 440C
63 STAINLESS STEEL METAL FERROUS FE CR 17-4PH
64 STAINLESS STEEL METAL FERROUS FE CR 304
65 STAINLESS STEEL METAL FERROUS FE CR 316
66 STAINLESS STEEL METAL FERROUS FE CR 347
67 STAINLESS STEEL METAL FERROUS FE CR 17-4 PH
68 STAINLESS STEEL METAL FERROUS FE CR 316
69 STAINLESS STEEL METAL FERROUS FE CR 316
70 STAINLESS STEEL METAL FERROUS FE CR 17-4 PH
71 STAINLESS STEEL METAL FERROUS FE CR 410
72 STAINLESS STEEL METAL FERROUS FE CR 15-5PH
73 STAINLESS STEEL METAL FERROUS FE CR 410
74 STAINLESS STEEL METAL FERROUS FE CR 21-55N
75 STAINLESS STEEL METAL FERROUS FE CR 310
76 STEEL METAL FERROUS FE CR 52100
77 STEEL METAL FERROUS FE CR 52100
78 STEEL METAL FERROUS FE CR 52100
TABLE 15.1 Tribomaterials Database (Part B)
SPECIFICATION FORM PROCESSING AND TREATMENTPROCESSING CONDITIONS
SELF BOND
CO BONDED
MOULDED CARBPM GRAPHITE, HIGH TEMP. TREATED
SILVER IMPREGNATED
MOULDED
BAKED
MOULDED
BAKED
BAKED
BAKED, IMPREGNATED
BABBITT IMPREGNATED
SILVER IMPREGNATED
EXTRUDED
CAST
CAST
SELF BOND
HOT PRESS
MOULDED MOLYBDENUM DISULFIDE, BONDED
COATING ON STEEL SINTERED
PLATE SINTERED
CAST
CAST
CAST ANNEALED
CAST
CAST
CAST
POROUS, 8%
ELECTROLYTIC ANNEALED
SAE 863; ASTM B-439-70, GR4; MIL-B-5687C, 2B POROUS, 20%
SAE 862; ASTM B-439-70, GR3; MIL-B-5687C, 2B POROUS, 20%
SAE 850; ASTM B-439-70, GR1; MIL-B-5687C, 2A1 POROUS, 20%
COLD ROLLED
ANNEALED
HT 600F TEMPER
WROUGHT, H900
ANNEALED
ANNEALED
HOT WORKED, ANNEALED
BAR HT 925F:4h
BAR ANNEALED H-900
BAR ANNEALED H-900
BAR HT H-1100
ANNEALED
WROUGHT, H900
HT 1000 TEMPER
ANNEALED
ANNEALED
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
TABLE 15.1 Tribo-Materials Database (Part A)
NUMBER COMMON NAME CLASS SUBCLASSPRINCIPAL
COMPONENTSECOND
COMPONENT GRADE
79 STEEL METAL FERROUS FE CR 52100
80 STEEL METAL FERROUS FE CR 52100
81 STEEL METAL FERROUS FE CR 52100
82 STEEL METAL FERROUS FE CR 52100
83 STEEL METAL FERROUS FE CR 52100
84 STEEL METAL FERROUS FE CR 52100
85 STEEL METAL FERROUS FE C 1090
86 STEEL METAL FERROUS FE MN 1020
87 STEEL METAL FERROUS FE CR 52100
88 STEEL METAL FERROUS FE CR 52100
89 STEEL METAL FERROUS FE CR 52100
90 STEEL METAL FERROUS FE CR 52100
91 STEEL METAL FERROUS FE CR 52100
92 STEEL METAL FERROUS FE CR 52100
93 STEEL METAL FERROUS FE CR 52100
94 STEEL METAL FERROUS FE CR 52100
95 STEEL METAL FERROUS FE CR 52100
96 STEEL METAL FERROUS FE CR 52100
97 STEEL METAL FERROUS FE CR 52100
98 STEEL METAL FERROUS FE CR 52100
99 STEEL METAL FERROUS FE CR 52100
100 STEEL METAL FERROUS FE CR 52100
101 STEEL METAL FERROUS FE CR 52100
102 STEEL METAL FERROUS FE CR 52100
103 STEEL METAL FERROUS FE CR 52100
104 STEEL METAL FERROUS FE CR 52100
105 STEEL METAL FERROUS FE CR 52100
106 STEEL METAL FERROUS FE CR 52100
107 STEEL METAL FERROUS FE C 1090
108 STEEL METAL FERROUS FE CR 52100
109 STEEL METAL FERROUS FE CR 52100
110 STEEL METAL FERROUS FE CR 52100
111 STEEL METAL FERROUS FE CR 52100
112 STEEL METAL FERROUS FE CR 52100
113 STEEL METAL FERROUS FE CR 52100
114 STEEL METAL FERROUS FE CR 52100
115 STEEL METAL FERROUS FE CR 52100
116 STEEL METAL FERROUS FE CR 52100
117 STEEL METAL FERROUS FE CR 52100
118 STEEL METAL FERROUS FE CR 52100
119 STEEL METAL FERROUS FE CR 52100
120 STEEL METAL FERROUS FE CR 52100
121 STEEL METAL FERROUS FE CR 52100
122 STEEL METAL FERROUS FE CR 52100
123 STEEL METAL FERROUS FE CR 52100
124 STEEL METAL FERROUS FE CR 52100
125 STEEL METAL FERROUS FE CR 52100
126 STEEL METAL FERROUS FE CR 52100
127 STEEL METAL FERROUS FE CR 52100
128 STEEL METAL FERROUS FE CR 52100
129 STEEL METAL FERROUS FE C 1090
130 STEEL METAL FERROUS FE CR 52100
131 STEEL METAL FERROUS FE CR 52100
132 STEEL METAL FERROUS FE CR 52100
133 STEEL METAL FERROUS FE CR 52100
134 STEEL METAL FERROUS FE CR 52100
135 STEEL METAL FERROUS FE CR 52100
136 STEEL METAL FERROUS FE CR 52100
137 STEEL METAL FERROUS FE CR 52100
138 STEEL METAL FERROUS FE CR 52100
139 STEEL METAL FERROUS FE CR 52100
140 STEEL METAL FERROUS FE CR 52100
141 STEEL METAL FERROUS FE CR 52100
142 STEEL METAL FERROUS FE CR 52100
143 STEEL METAL FERROUS FE CR 52100
144 STEEL METAL FERROUS FE CR 52100
145 STEEL METAL FERROUS FE CR 52100
146 STEEL METAL FERROUS FE CR 52100
147 STEEL METAL FERROUS FE CR 52100
148 STEEL METAL FERROUS FE CR 52100
149 STEEL METAL FERROUS FE CR 52100
150 STEEL METAL FERROUS FE CR 52100
151 STEEL METAL FERROUS FE CR 52100
152 STEEL METAL FERROUS FE CR 52100
153 STEEL METAL FERROUS FE CR 52100
154 STEEL METAL FERROUS FE CR 52100
155 STEEL METAL FERROUS FE CR 52100
TABLE 15.1 Tribomaterials Database (Part B)
SPECIFICATION FORM PROCESSING AND TREATMENTPROCESSING CONDITIONS
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
SHEET NORMALIZED 1650F
SHEET ANNEALED 1610F:1h, FURNACE COOLED
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
SHEET NORMALIZED 1650F
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
SHEET NORMALIZED 1650F
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
TABLE 15.1 Tribo-Materials Database (Part A)
NUMBER COMMON NAME CLASS SUBCLASSPRINCIPAL
COMPONENTSECOND
COMPONENT GRADE
156 STEEL METAL FERROUS FE CR 52100
157 STEEL METAL FERROUS FE CR 52100
158 STEEL METAL FERROUS FE CR 52100
159 STEEL METAL FERROUS FE CR 52100
160 STEEL METAL FERROUS FE CR 52100
161 STEEL METAL FERROUS FE CR 52100
162 STEEL METAL FERROUS FE CR 52100
163 STEEL METAL FERROUS FE CR SS UNILOY 19-9DL
164 STEEL METAL FERROUS FE CR 52100
165 STEEL METAL FERROUS FE CR 52100
166 STEEL METAL FERROUS FE CR 52100
167 STEEL METAL FERROUS FE CR 52100
168 STEEL METAL FERROUS FE CR 52100
169 STEEL METAL FERROUS FE CR 52100
170 STEEL METAL FERROUS FE CR 52100
171 STEEL METAL FERROUS FE CR 52100
172 STEEL METAL FERROUS FE CR 52100
173 STEEL METAL FERROUS FE CR 52100
174 STEEL METAL FERROUS FE CR 52100
175 STEEL METAL FERROUS FE CR 52100
176 STEEL METAL FERROUS FE CR 52100
177 STEEL METAL FERROUS FE CR 52100
178 STEEL METAL FERROUS FE CR SS A-286
179 STEEL METAL FERROUS FE CR 52100
180 STEEL METAL FERROUS FE CR 52100
181 STEEL METAL FERROUS FE C 81B45
182 STEEL METAL FERROUS FE C 9310
183 STEEL METAL FERROUS FE C 51100
184 STEEL METAL FERROUS FE C 50100
185 STEEL METAL FERROUS FE C 4820
186 STEEL METAL FERROUS FE C C1080
187 STEEL METAL FERROUS FE C 9310
188 STEEL METAL FERROUS FE CR 52100
189 STEEL METAL FERROUS FE MN C1080
190 STEEL METAL FERROUS FE CR FERRO TIC
191 STEEL METAL FERROUS FE C 8620
192 STEEL METAL FERROUS FE C 81B45
193 STEEL METAL FERROUS FE C 4820
194 STEEL METAL FERROUS FE CR 52100
195 STEEL METAL FERROUS FE MN 1118
196 STEEL METAL FERROUS FE MN 1118
197 STEEL METAL FERROUS FE C 8620
198 STEEL METAL FERROUS FE C 4340
199 STEEL METAL FERROUS FE CR SS UHB AEB-L
200 STEEL METAL FERROUS FE AL SUPER NITRALLOY
201 STEEL METAL FERROUS FE AL SUPER NITRALLOY
202 STEEL METAL FERROUS FE CR 52100
203 STEEL METAL FERROUS FE C 4340
204 STEEL METAL FERROUS FE C 1040
205 STEEL METAL FERROUS FE C 1040
206 STEEL METAL FERROUS FE CR 52100 MOD
207 TOOL STEEL METAL FERROUS FE W M2
208 TOOL STEEL METAL FERROUS FE CR D2
209 TOOL STEEL METAL FERROUS FE CR M50
210 TOOL STEEL METAL FERROUS FE Cr M50
211 TOOL STEEL METAL FERROUS FE CR H13
212 TOOL STEEL METAL FERROUS FE CR D2
213 TOOL STEEL METAL FERROUS FE CR D2
214 TOOL STEEL METAL FERROUS FE CR H11
215 ALUMINUM METAL NONFERROUS AL SI 380
216 ALUMINUM METAL NONFERROUS AL
217 ALUMINUM METAL NONFERROUS AL SI 390
218 ALUMINUM METAL NONFERROUS AL FE 1100
219 ALUMINUM ALLOY METAL NONFERROUS AL CD
220 ALUMINUM BRONZE METAL NONFERROUS CU AL C61000
221 ALUMINUM BRONZE METAL NONFERROUS CU AL C61000
222 ALUMINUM BRONZE METAL NONFERROUS CU AL
223 ALUMINUM BRONZE METAL NONFERROUS CU AL C60800
224 ALUMINUM-BIMETAL METAL NONFERROUS AL SN
225 ALUMINUM-LEAD METAL NONFERROUS AL PB
226 ALUMINUM-SILICON METAL NONFERROUS AL SI
227 ALUMINUM-TIN METAL NONFERROUS AL SN
228 ALUMINUM, OIL-FILLED METAL NONFERROUS AL CU
229 ANTIMONY METAL NONFERROUS SB
230 BERYLLIUM COPPER METAL NONFERROUS CU BE
231 BERYLLIUM COPPER METAL NONFERROUS CU BE
232 BRONZE METAL NONFERROUS CU SN C93200
TABLE 15.1 Tribomaterials Database (Part B)
SPECIFICATION FORM PROCESSING AND TREATMENTPROCESSING CONDITIONS
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
HOT ROLLED
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
BAR HT 350F TEMPER
QUENCHED, TEMPERED
BAR HT 350F TEMPER
HT 900F TEMPER
HT 400F TEMPER
CARBURIZED, HT 300F, TEMPER
ANNEALED
ANNEALED
CAST ANNEALED
ANNEALED
ANNEALED
ANNEALED
HT 400F TEMPER
ANNEALED
ANNEALED
CARBURIZED, HT 300F TEMPER
BAR HT 350F TEMPER
CARBURIZED, HT 300F TEMPER
ANNEALED
CARBURIZED, HT 300F TEMPER
HT 260C TEMPER
PH
PH,NITRIDED
BAR HT 350F TEMPER
ANNEALED
HT 300F TEMPER
ANNEALED
ANNEALED
HT 300F TEMPER
BAR HT 1850F, TEMPER 400F, 1 h
HT 600F TEMPER
ANNEALED
BAR HT 25min.1875F, 2 TEMPER 1100F,2h
HT 600F TEMPER
BAR HT 1850F, TEMPER 400F, 1 h
HT 500F TEMPER
CAST
ANNEALED
CAST
SAE 781
HARDENED
CAST ANNEALED
CDA 954
CAST ANNEALED
SAE 780
SAE 783
POROUS, 19%
ANNEALED
CAST AGE HARDENED
CAST ANNEALED
SAE 660 CAST ANNEALED
TABLE 15.1 Tribo-Materials Database (Part A)
NUMBER COMMON NAME CLASS SUBCLASSPRINCIPAL
COMPONENTSECOND
COMPONENT GRADE
233 BRONZE METAL NONFERROUS CU PB C98600
234 BRONZE METAL NONFERROUS CU PB C94300
235 BRONZE METAL NONFERROUS CU SN C93700
236 BRONZE, OIL-FILLED METAL NONFERROUS CU SN
237 BRONZE, OIL-FILLED METAL NONFERROUS FE CU
238 CADMIUM METAL NONFERROUS CD
239 CADMIUM ALLOY METAL NONFERROUS CD NI
240 CAST ALUMINUM ALLOY METAL NONFERROUS AL SN
241 COPPER METAL NONFERROUS CU OFHC
242 COPPER-LEAD METAL NONFERROUS CU PB
243 COPPER-LEAD METAL NONFERROUS CU PB
244 ELECTROLESS NICKEL METAL NONFERROUS NI P
245 ELECTROLESS NICKEL METAL NONFERROUS NI P
246 GOLD METAL NONFERROUS AU
247 GUN METAL METAL NONFERROUS CU SN
248 HASTELLOY METAL NONFERROUS NI MO C
249 INCONEL METAL NONFERROUS NI CR 718
250 INDIUM METAL NONFERROUS IN
251 LEAD METAL NONFERROUS PB
252 LEAD BABBITT METAL NONFERROUS PB SB 15
253 LEAD BABBITT METAL NONFERROUS PB SB 13
254 LEAD BABBITT METAL NONFERROUS PB SB 7
255 LEAD BABBITT METAL NONFERROUS PB SB 8
256 LEADED GUN METAL METAL NONFERROUS CU SN
257 LEAD-TIN BRONZE METAL NONFERROUS CU SN
258 LEAD-TIN BRONZE METAL NONFERROUS CU SN
259 MANGANESE BRONZE METAL NONFERROUS CU ZN C86300
260 MOLYBDENUM METAL NONFERROUS MO TI 0.5 TI
261 MONEL METAL NONFERROUS NI CU K500
262 NAVY GUN METAL METAL NONFERROUS CU SN
263 NICKEL-CHROMIUM ALLOY METAL NONFERROUS FE NI 16-25-6
264 NICKEL-CHROMIUM ALLOY METAL NONFERROUS FE NI 16-25-6
265 PHOSPHOR BRONZE METAL NONFERROUS CU SN
266 PHOSPHOR BRONZE METAL NONFERROUS CU SN C51100
267 SEMIPLASTIC BRONZE METAL NONFERROUS CU SN
268 SILICON BRONZE METAL NONFERROUS CU SI C87200
269 SILVER METAL NONFERROUS AG
270 STELLITE METAL NONFERROUS CO CR S1016
271 STELLITE METAL NONFERROUS CO CR 1
272 STELLITE METAL NONFERROUS CO CR 6
273 STELLITE METAL NONFERROUS CO CR F
274 STELLITE METAL NONFERROUS CO CR STAR J
275 STELLITE METAL NONFERROUS CO CR S1016
276 STELLITE METAL NONFERROUS CO CR S1016
277 STOODY METAL NONFERROUS CO CR 6
278 Ti-6Al-4V METAL NONFERROUS TI AL
279 Ti-6Al-4V METAL NONFERROUS TI AL
280 TIN METAL NONFERROUS SN
281 TIN BABBITT METAL NONFERROUS SN SB 3
282 TIN BABBITT METAL NONFERROUS SN SB 2
283 TIN BABBITT METAL NONFERROUS SN SB 1
284 TIN BABBITT METAL NONFERROUS SN SB
285 TRIBALOY METAL NONFERROUS CO MO T-800
286 TRIBALOY METAL NONFERROUS CO MO T-400
287 TRIBALOY METAL NONFERROUS NI MO T-700
288 TUNGSTEN METAL NONFERROUS W NI
289 VANASIL METAL NONFERROUS SI NI 77
290 WASPALOY METAL NONFERROUS NI CR
291 WASPALOY METAL NONFERROUS NI CR
292 WAUKESHA METAL NONFERROUS NI SN 23
293 ZINC METAL NONFERROUS ZN
294 ZINC-11 ALUMINUM METAL NONFERROUS ZN AL 12
295 ZINC-27 ALUMINUM METAL NONFERROUS ZN AL 27
296 ZIRCALLOY METAL NONFERROUS ZR SN 2
297 ACETAL POLYMER
298 ACRYLONITRILE-BUTADIENE-STYRENE (ABS) POLYMER
299 ARMALON POLYMER
300 DUROID POLYMER 5600
301 FEP POLYMER
302 IPC POLYMER 1832
303 NYLON POLYMER 6
304 NYLON POLYMER TF
305 NYLON 6/6 POLYMER
306 PHENOLIC POLYMER
307 POLYCARBONATE POLYMER
308 POLYESTER POLYMER
309 POLYETHYLENE POLYMER
310 POLYIMIDE POLYMER
TABLE 15.1 Tribomaterials Database (Part B)
SPECIFICATION FORM PROCESSING AND TREATMENTPROCESSING CONDITIONS
CAST ANNEALED
CAST ANNEALED
SAE 64 CAST ANNEALED
SAE 841; ASTM b-438-73, GR1 TYPE II; MIL-B-5678C, 1A POROUS, 20%
ASTM B-612-70, GR3 POROUS, 20%
ANNEALED
SAE 770 CAST
ANNEALED
SAE 480
PLATED HEATED TO 400C
PLATED AS DEPOSITED
ANNEALED
SAE 62, CDA 902
CAST ANNEALED
CAST AGED
ANNEALED
ANNEALED
SAE 15 CAST
SAE 13 CAST
ASTM 7 CAST
ASTM B23/8 CAST
SAE 63, CDA 927
SAE 40, CDA 836
CDA943
CAST ANNEALED
ARC CAST
CAST
SAE 620, CDA 903
HOT ROLLED, HARDENED
HOT ROLLED, ANNEALED
SAE 64, SAE 792; SAE 797, CDA 937
COLD WORKED
SAE 67, CDA 938
CAST ANNEALED
ANNEALED
BAR WELD OXY/ACETY
CAST
CAST
CAST
CAST
BAR WELD OXY/ACETY
BAR WELDED OXY/ACETY
CAST
CAST ANNEALED
BORONIZED, HT
ANNEALED
ASTM B23/3 CAST
ASTM B23/2 CAST
CAST
SAE 11
CAST
CAST
CAST
PM SINTER, DRAWN
CAST AGE HARDENED
CAST ANNEALED
CAST HT, PH
CAST
ANNEALED
CAST
ASTM B-669-82 CAST
CAST ANNEALED
MOULDED
CAST
CAST
CAST
LAMINATED
TABLE 15.1 Tribo-Materials Database (Part A)
NUMBER COMMON NAME CLASS SUBCLASSPRINCIPAL
COMPONENTSECOND
COMPONENT GRADE
311 POLYIMIDE (FILLED) POLYMER T-0454
312 POLYPHENYLENE OXIDE POLYMER
313 POLYPHENYLENE SULFIDE POLYMER
314 POLYPROPYLENE POLYMER
315 POLYSULFONE POLYMER
316 POLYURETHANE POLYMER
317 PTFE POLYMER
318 TORLON POLYMER
319 UHMWPE POLYMER
320 RUBBER POLYMER ELASTOMER
321 ACETAL-CARBON POLYMER FILLED
322 ACETAL-GLASS POLYMER FILLED
323 ACETAL-PTFE POLYMER FILLED
324 ACETAL-SILICONE POLYMER FILLED
325 ACRYLONITRILE-BUTADIENE-STYRENE (ABS) POLYMER FILLED PTFE
326 EPOXY-CELLULOSE POLYMER FILLED
327 NYLON 6/6-CARBON POLYMER FILLED
328 NYLON 6/6-GLASS POLYMER FILLED
329 NYLON 6/6-PTFE POLYMER FILLED
330 NYLON 6/6-SILICONE POLYMER FILLED
331 PEEK-GRAPHITE POLYMER FILLED
332 PHENOLIC-COTTON LAMINATE POLYMER FILLED
333 PHENOLIC-WOOD FLOUR POLYMER FILLED
334 POLYCARBONATE-CARBON POLYMER FILLED
335 POLYCARBONATE-GLASS POLYMER FILLED
336 POLYCARBONATE-PTFE POLYMER FILLED
337 POLYESTER-CARBON POLYMER FILLED
338 POLYESTER-GLASS POLYMER FILLED
339 POLYESTER-PTFE POLYMER FILLED
340 POLYESTER-SILICONE POLYMER FILLED
341 POLYETHYLENE-PTFE POLYMER FILLED
342 POLYIMIDE-GLASS POLYMER FILLED
343 POLYIMIDE-GRAPHITE POLYMER FILLED
344 POLYPHENYLENE OXIDE-GLASS POLYMER FILLED
345 POLYPHENYLENE OXIDE-PTFE POLYMER FILLED
346 POLYPHENYLENE SULFIDE-CARBON POLYMER FILLED
347 POLYPHENYLENE SULFIDE-GLASS POLYMER FILLED
348 POLYPHENYLENE SULFIDE-PTFE POLYMER FILLED
349 POLYPROPYLENE-PTFE POLYMER FILLED
350 POLYSULFONE-CARBON POLYMER FILLED
351 POLYSULFONE-GLASS POLYMER FILLED
352 POLYSULFONE-PTFE POLYMER FILLED
353 POLYURETHANE-GLASS POLYMER FILLED
354 POLYURETHANE-PTFE POLYMER FILLED
355 PTFE-FABRIC POLYMER FILLED
356 PTFE-GLASS POLYMER FILLED
357 PTFE-GRAPHITE POLYMER FILLED
358 RULON POLYMER FILLED LD
359 RYTON POLYMER FILLED R4
360 VESPEL POLYMER FILLED SP1
361 VESPEL POLYMER FILLED SP21
362 BUTYL POLYMER RUBBER
363 NEOPRENE POLYMER RUBBER
364 NITRILE POLYMER RUBBER
365 SILICONE RUBBER POLYMER RUBBER
366 URETHANE POLYMER RUBBER
367 VITON POLYMER RUBBER
368 FABROID POLYMER WOVEN
TABLE 15.1 Tribomaterials Database (Part B)
SPECIFICATION FORM PROCESSING AND TREATMENTPROCESSING CONDITIONS
MOULDED
MOULDED
MOULDED
SINTERED
SINTERED
MOULDED
MOULDED
MOULDED
MOULDED
MOULDED
MOULDED
WOVEN
TABLE 15.1 Tribomaterials Database (Part C)
Number Component NamesComponent
Weight PercentDensity (kg/m3)
Melting Point (C)
Expansion Coefficient (µm/m)
Thermal Conductivity (watt/m/C)
Heat Capacity (kJ/kg C)
1 4,429 8 26 1.0
2 2,510 2,400 5 19 2.0
3 6,643 1,890 10 19 1.0
4 3,045 2,699 4 147 1.0
5 4,429 3,140 8 26 1.0
6 5,536 9 17 1.0
7 6,089 10 19
8 3,045 2,800 6 2 0.0
9 C 1,938 1 36
10 C, Ag 2,353 5 26
11 8,304 4 138
12 C 1,850 5
13 C 1,661 4 12
14 C 1,938 3,652 8 2 1.0
15 C 1,938 8 69
16 C 1,661 10 17
17 C 1,661 9 9
18 1,700 5 9
19 C, Babbitt 2,350 5 13
20 C, copper 2,400 5 14
21 C, glass 2,000 5 78
22 C, lithium fluoride 1,900 9 17
23 C, resin 1,900 5 9
24 C, silver 2,400 5 14
25 C 1,570 2 170
26 2,491 1,538 57 2 1.0
27 2,491 1,122 10 1 1.0
28 3,045 1,899 2 15 1.0
29 5,536 2,950 8 66 1.0
30 3,875 1,849 7 35 0.0
31 Al2O3, TiO2 4,152 1,750 8 25 1.0
32 2,214 2,570 36 2 2.0
33 Y2O3,ZrO2 5.3,94 6,089 2,700 10 3
34 20 1.0
35 ZrO2, MgO 5,536 10 2
36
37 Y2O3,Zr02 3,97 5,813 2,593 10 3
38 3,045 1,710 16 164 1.0
39 4,152 1,838 9 5 1.0
40 1,200 5 2.0
41 MoS2, Ta 5,900 9 43
42 PTFE, Pb, bronze 19 42
43 TiC,Cr,Mo,C,Fe 34.6,6.6,2,.8,56 7,750
44 14,200 6 87
45 14,200 6 87
46 C,Si,Ni,Cu,Cr,Fe 3,1.5,15,6,2,71.5 7,197 10 40
47 C,Si,Mn,Ni,Cr,Fe 3.5,1.5,0.5,6,8,80.5 7,473 10
48 C,Si,Mn,P,S,Fe .85,14.5,.5,.07,.08,84 7,197 1,269 12 1.0
49 C,Si,Ni,Cr,Fe 3.5,.5,4,2,89.5 7,473 9 17
50 C,Cr,Fe 2.8,28,69.2 7,473 9
51 C,Mn,Si,Cu,Ni,Mo,Fe 3,2,1.8,.5,2,.5,90.2 7,197 8 0.0
52 C, Fe 3, 97 6,700 16
53 C,Fe .006,99.98 7,861 1,537 12 54 0.0
54 Cu, Fe 20, 80 6,000 12
55 Cu, Fe 10, 90 6,100 13 29
56 Fe 6,000 10 28
57 7,800 23 50
58 C,Mn,Si,Cr,Ni,Mo,Ti,Va,Fe .08,1,.6,15,26,1,2,.3,54 7,473
59 C,Mn,P,S,Si,Cr,Ni,N,Fe .08,2,.045,.03,1,18,8,.2,70.6 8,027 1,427 17 16 0.0
60 C,Cr,Ni,Mo,Fe .1,18,14,3,65 8,027 1,427 11 16 0.0
61 C,Mn,Si,P,S,Cr,Mo,Fe 1,1.25,1,.04,.04,18,.75,78 7,473 1,538 11 29 0.0
62 C,Mn,Si,P,S,Cr,Mo,Fe 1,1.25,1,.04,.04,18,.75,78 7,473 1,538 11 29 0.0
63 C,Cr,Ni,Cu,Fe .05,16.5,4.0,4.0,75.5 7,750 1,400 11 18 0.0
64 C,Cr,Ni,Fe .08,19,10,71 8,030 17 1.0
65 C,Cr,Ni,Mo,Fe .1,18,14,3,65 8,027 1,427 11 16 0.0
66 C,Mn,Si,Cr,Fe .15,1.0,.5,12,86.5 7,889 1,400 19 16 1.0
67 C,Cr,Ni,Cu,Fe .07,17,4,4,74 7,750 11 21 1.0
68 C,Cr,Ni,Mo,Fe .08,18,14,3,64 8,027 1,427 11 16 0.0
69 C,Cr,Ni,Mo,Fe .08,18,14,3,64 8,027 1,427 11 16 1.0
70 C,Cr,Ni,Cu,Fe .07,17,4,4,74 7,750 1.0
71 C,Mn,Si,Cr,Fe .15,1.0,.5,12,86.5 7,750 1,482 12 25 0.0
72 C,Mn,P,S,Si,Cr,Ni,Cu,Cb,Fe .07,1.0,.04,.03,1,14.5,4,3,.3,76 7,750 18
73 C,Mn,P,S,Si,Cr,Ni,Cb&Ta .08,2,.045,.03,1,18,11,.1 7,750 1,482 12 25 0.0
74 C,Mn,Si,Cr,Ni,N,Fe .52,9,.15,21,3.85,.45,65 7,750 16
75 C,Mn,Si,Cr,Ni,Fe .25,2,1.5,25,20,47 7,970 1,427 16 16 1.0
76 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
77 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
78 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
TABLE 15.1 Tribomaterials Database (Part D)
Resistivity (u-ohm-cm) Hardness
Tensile Strength (MPa)
Youngs Modulus (MPa)
Fracture Toughness (MPa-m1/2) Data Source
Wear Coefficient
Maximum Operating Temperature (C)
Wear Rate (mm3/m)
3500 HV 345,000 7 Glaeser
3200 HV 172 441,000 6 Glaeser
2600 HV 262 372,000 Glaeser
100 2700 HV 103 379,000 5 Glaeser 1,650
100 3000 HV 896 483,000 Glaeser
3000 HV 345 414,000 Glaeser
1400 HV 407,000 Glaeser
1500 HV 896 552,000 12 Glaeser 3.0E-06 9.5E-07
41 6,890 Glaeser 649
2 820 HV 69 32,344 Glaeser 260
650 HV 97 13,800 Glaeser 371
650 HV 59 14,500 Glaeser 650
4 480 HV 28 14,500 Glaeser 288
3 170 HV 21 20,700 Glaeser 204
600 HV 38 12,400 Glaeser 538
2 320 HV 28 6,890 Glaeser 288
5 680 HV 41 13,800 Glaeser 6.1E-05 316 2.4E-04
85 SHORE 41 16,600 Booser 316
4 70 SHORE 62 32,344 Booser 190
95 SHORE 62 32,348 Booser 260
90 SHORE 52 15,200 Booser 649
90 SHORE 48 20,700 Booser 260
90 SHORE 59 32,612 Booser 260
90 SHORE 69 32,560 Booser 260
3 HV 12 12,900 Glaeser 425
1.00E+12 110 129,744 1 Glaeser 1,650
0580 HV 130,340 1 Glaeser
1300 HV 524 310,000 4 Glaeser 1,480
60 2000 HV 248,000 Glaeser
1500 HV 262 372,000 4 Glaeser 1,760
545 358,000 5 Glaeser
1800 HV 103 379,000 Glaeser
1158 HV 1,172 200,000 7 Glaeser
276 200,000 10 Glaeser 1,370
1600 HV 689 200,000 9 Glaeser
172 172,000 10 Glaeser 1,370
286 HV 1,020 205,000 9 Glaeser 1,480
1.46E+20 853 HV 103 379,000 1 Glaeser 2,400
400 900 HV 52 234,000 3 Glaeser
4.01E+13 8 12,400 Booser 71
675 HV 69 138,000 Glaeser 400
Glaeser 204
330 HV 1,034 Glaeser 649
85 HRA 1,100 607,000 ASTM G2,RR2,12/9/75,5 labs,n=5 3.0E-05 4.5E-04
90 HRA 1,103 607,000 Booser 538
150 HV 207 103,000 Glaeser 538
560 HV 620 172,000 Glaeser 816
71 530 HV 110 Glaeser
655 HV 379 172,000 Glaeser 816
530 HV 689 221,000 98 Glaeser 427
196 HV 310 124,000 Glaeser 399
30 HB 138 129,528 Booser 135
10 45 HV 276 207,000 Glaeser
83 HB 221 Booser 135
207 Booser 135
50 HB 83 Booser 135
150 HB 414 200,000 140 Booser 538
200,000 Glaeser
72 200 HV 689 200,000 Glaeser
74 200 HV 758 196,000 Glaeser 649
60 257 HV 862 200,000 Glaeser 316
60 650 HV 1,379 200,000 Glaeser 3.0E-05 316 6.0E-05
77 400 HV 1,379 196,000 48 Glaeser
160 HV 586 193,000 Glaeser 7.6E-06 870 1.7E-03
74 150 HV 586 196,000 Glaeser 649
72 150 HV 620 193,000 Glaeser 815
77 44 HRC 1,379 196,000 48 ASTM G2,RR3,5/18/76,3 labs,n=3 2.0E-03 1.7E-02
74 97 HRB 760 196,000 ASTM G2,RR2,12/9/75,5 labs,n=5 9.0E-04 1.9E-02
74 97 HRB 680 196,000 ASTM G2,RR1,5/23/75,2 labs,n=2 4.0E-04 8.7E-03
77 44 HRC 1,379 196,000 48 ASTM G2,RR9,6/10/82,8 labs,n=32 3.0E-03 8.5E-02
57 135 HV 517 196,000 Glaeser 649
77 420 HV 1,379 196,000 81 Glaeser
57 257 HV 758 196,000 Glaeser 649
264 HV 862 193,000 60 Glaeser 538
78 150 HV 654 200,000 Glaeser 1.5E-05 927 3.8E-03
20 62 HRC 1,640 199,000 Hughes/Rowe 3.7E-09 200 3.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 8.0E-09 200 1.2E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 3.0E-07 200 2.4E-06
TABLE 15.1 Tribomaterials Database (Part C)
Number Component NamesComponent
Weight PercentDensity (kg/m3)
Melting Point (C)
Expansion Coefficient (µm/m)
Thermal Conductivity (watt/m/C)
Heat Capacity (kJ/kg C)
79 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
80 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
81 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
82 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
83 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
84 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
85 C,Mn,P,S,Fe .9,.9,.04,.05,98 7,750 1,482 11 50 1.0
86 C,Mn,P,S,Fe .2,.6,.04,.05,99 7,750 1,482 11 50 1.0
87 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
88 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
89 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
90 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
91 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
92 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
93 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
94 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
95 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
96 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
97 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
98 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
99 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
100 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
101 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
102 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
103 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
104 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
105 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
106 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
107 C,Mn,P,S,Fe .9,.9,.04,.05,98 7,750 1,482 11 50 1.0
108 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
109 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
110 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
111 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
112 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
113 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
114 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
115 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
116 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
117 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
118 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
119 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
120 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
121 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
122 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
123 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
124 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
125 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
126 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
127 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
128 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
129 C,Mn,P,S,Fe .9,.9,.04,.05,98 7,750 1,482 11 50 1.0
130 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
131 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
132 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
133 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
134 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
135 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
136 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
137 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
138 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
139 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
140 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
141 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
142 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
143 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
144 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
145 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
146 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
147 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
148 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
149 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
150 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
151 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
152 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
153 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
154 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
155 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
TABLE 15.1 Tribomaterials Database (Part D)
Resistivity (u-ohm-cm) Hardness
Tensile Strength (MPa)
Youngs Modulus (MPa)
Fracture Toughness (MPa-m1/2) Data Source
Wear Coefficient
Maximum Operating Temperature (C)
Wear Rate (mm3/m)
20 62 HRC 1,640 199,000 Hughes/Rowe 3.0E-08 200 2.2E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-08 200 2.4E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 1.0E-08 200 1.2E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 1.1E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 1.2E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 1.8E-06
19 27 HRC 207,000 ASTM G2,RR4,11/4/76,5 labs,n=5 4.0E-04 1.9E-02
19 60 HRB 400 207,000 ASTM G2,RR8,5/20/81,7 labs,n=28 7.0E-04 8.4E-02
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 1.9E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 3.8E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-09 200 1.4E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 9.5E-07 200 6.7E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 9.5E-07 200 3.9E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 3.7E-09 200 3.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 5.0E-09 200 3.8E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-08 200 3.3E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 8.0E-08 200 6.6E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-08 200 2.4E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 7.4E-09 200 6.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-08 200 1.3E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 1.2E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 8.0E-09 200 1.2E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 3.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 3.7E-09 200 2.8E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 3.0E-07 200 3.8E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 1.5E-06
19 27 HRC 207,000 ASTM G2,RR5,3/7/78,6 labs,n=30 4.0E-04 7.3E-03
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 9.3E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-08 200 3.5E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 3.0E-08 200 2.3E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 1.1E-05
20 62 HRC 1,640 199,000 Hughes/Rowe 1.0E-03 200 8.5E-03
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-10 200 1.7E-09
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 1.9E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 1.9E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 1.0E-02 200 8.5E-02
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-08 200 1.6E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 1.5E-05 200 1.2E-04
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 9.4E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 9.4E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 1.0E-08 200 1.2E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 3.7E-09 200 3.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 3.7E-09 200 3.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 5.9E-08 200 4.7E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 3.0E-07 200 2.4E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-09 200 1.8E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 5.9E-08
19 27 HRC 207,000 ASTM G2,RR4,11/4/76,5 labs,n=5 5.0E-04 8.3E-03
20 62 HRC 1,640 199,000 Hughes/Rowe 5.0E-09 200 3.8E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 3.0E-08 200 2.3E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 7.4E-09 200 6.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 5.9E-08 200 4.7E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-09 200 1.8E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 3.0E-07 200 2.9E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 8.0E-08 200 9.5E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 4.7E-07 200 3.8E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 1.9E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-08 200 3.5E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 5.0E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 3.7E-09 200 3.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 9.4E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 4.7E-07 200 3.0E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 1.0E-08 200 1.2E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 9.5E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 9.2E-10 200 5.0E-09
20 62 HRC 1,640 199,000 Hughes/Rowe 6.0E-07 200 5.3E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 7.0E-07 200 7.6E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 5.9E-08 200 4.7E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 1.0E-09 200 1.5E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 3.6E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 5.9E-08 200 4.5E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 5.0E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 3.6E-08
TABLE 15.1 Tribomaterials Database (Part C)
Number Component NamesComponent
Weight PercentDensity (kg/m3)
Melting Point (C)
Expansion Coefficient (µm/m)
Thermal Conductivity (watt/m/C)
Heat Capacity (kJ/kg C)
156 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
157 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
158 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
159 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
160 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
161 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
162 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
163 C,Mn,Si,Cr,Ni,Mo,W,Cb+Ta,Fe .4,1,.5,19,9,1.5,1.5,.4,67 7,916
164 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
165 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
166 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
167 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
168 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
169 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
170 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
171 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
172 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
173 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
174 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
175 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
176 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
177 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
178 C,Mn,Si,Cr,Mo,Va,Fe 1,1,1,15,4,.15,87.25 8,248
179 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
180 C,Mn,P,S,Si,Cr,Fe 1,.5,.025,.025,.3,1.5,96.5 7,800 1,475 12 43 0.0
181 C,Mn,Si,Ni,Cr,Mo,B,Fe .45,.8,.3,.3,.4,.1,.0005,98 7,750 13
182 C,Mn,Si,Cr,Ni,Mo,Fe .1,.5,.2,1.2,3.2,1,94.2 7,750 15 47 1.0
183 C,Mn,Si,Cr,Fe 1,.3,.2,.5,98.1 7,800 1,475 12 43 0.0
184 C,Mn,Si,Cr,Fe 1,.3,.2,1,97.5 7,800 1,475 12 43 0.0
185 C,Mn,P,S,Si,Ni,Mo,Fe .2,.6,.035,.04,.3,3.5,.25,95 7,861 16 45
186 C,Mn,Si,Fe .8,.7,.2,98 7,750 15 47 0.0
187 C,Mn,Si,Cr,Ni,Mo,Fe .1,.5,.2,1.2,3.2,1,94.2 7,750 15 47 1.0
188 C,Mn,P,S,Si,Cr,Fe 1,.5,.025,.025,.3,1.5,96.5 7,800 1,475 12 43 0.0
189 C,Mn,Si,Fe 1.0,12,.2,87 7,750 15 47 0.0
190 C,Mn,Si,Cr,Ni,Mo,V,Cb+Ta,Fe .15,.6,.4,12,.4,.6,.3,.3,85 6,366
191 C,Mn,Si,Cr,Ni,Mo,Fe .2,.8,.2,.5,.6,.2,97.5 7,750 1,507 15 38 0.0
192 C,Mn,Si,Ni,Cr,Mo,B,Fe .45,.8,.3,.3,.4,.1,.0005,98 7,750 13
193 C,Mn,P,S,Si,Ni,Mo,Fe .2,.6,.035,.04,.3,3.5,.25,95 7,861 1,510 16 45
194 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
195 C,Mn,Fe .16,1.4,98.44 7,805 12 52 0.0
196 C,Mn,Fe .16,1.4,98.44 7,805 12 52 0.0
197 C,Mn,Si,Cr,Ni,Mo,Fe .2,.8,.2,.5,.6,.2,97.5 7,750 15 38 0.0
198 C,Mn,P,S,Si,Ni,Cr,Mo,Fe .4,.7,.025,.025,.3,1.7,.8,.25,96 7,750 1,482 15 38 0.0
199 C,Mn,Si,Cr,Fe .68,.6,.38,13.2,85.2 7,750 649 28
200 C,Mn,Si,Ni,Cr,Mo,Al,Va,Fe .2,.3,.2,5,.5,.2,2,.1,92 7,750 12 52
201 C,Mn,Si,Ni,Cr,Mo,Al,Va,Fe .2,.3,.2,5,.5,.2,2,.1,92 7,750 12 52
202 C,Cr,Mn,Si 1.0,1.5,.5,.3 7,800 1,475 12 43 0.0
203 C,Mn,P,S,Si,Ni,Cr,Mo,Fe .4,.7,.025,.025,.3,1.7,.8,.25,96 7,750 1,482 15 38 0.0
204 C,Mn,P,S,Si,Fe .4,.7,.04,.05,.2,98.6 7,750 1,482 11 50 0.0
205 C,Mn,P,S,Si,Fe .4,.7,.04,.05,.2,98.6 7,750 1,482 11 51 1.0
206 C,Mn,Si,Cr,Fe 1,1,.6,1,96.4 7,800 1,475 12 43 0.0
207 C,W,Mo,Cr,V,Fe .8,6,5,4,2,82.2 8,027 10 38
208 C,Cr,V,Si,Mn,Fe 1.6,13,1,.6,.6,83 7,750
209 C,Mn,Si,P,S,Cr,Ni,V,Mo,Fe .8,.25,.25,.015,.015,4,.1,1,4.5,89 7,890 11
210 C,Mn,Si,P,S,Cr,Ni,V,Mo,Fe .8,.25,.25,.015,.015,4,.1,1,4.5,89 7,890 11
211 C,Cr,Mo,V,Si,Fe .35,5,1.5,1,1,91 7,750 16 29
212 C,Cr,Mo,V,Si,Mn,Fe .35,5,1.5,.4,.9,.3,91.6 7,750 10
213 C,Cr,V,Si,Mn,Fe 1.6,13,1,.6,.6,83 7,750
214 C,Si,Mn,Cr,V,Mo,Fe 1.5,.4,.3,12,.4,1,96.5 7,750 16 29
215 Cu,Si,Fe,Mn,Mg,Zn,Ni,Al 3.5,8,2,.5,.1,1,.5,84.5 2,768 650 40 97 1.0
216 Al 2,685 649 24 221 1.0
217 Cu,Si,Fe,Mn,Mg,Zn,Ti,Al 4.5,17,1,.1,.5,.1,.2,77.5 2,491 510 11 134
218 Si + Fe, Cu, Mn, Zn, Al 1, .1, .05, .1, 99 2,713 649 22 221 1.0
219 Al, Si, Cd 95, 4, 1
220 Cu,Al 92,8 7,760 1,041 18 69 0.0
221 Cu,Al 92,8 7,760 1,041 18 69 0.0
222 Cu, Al, Fe 85, 11, 4 7,500 1,045 16 59
223 Cu,Al 95,5 8,304 1,054 18 80 0.0
224 Al, Sn, Cu, Ni, Si 90, 6.5, 1, 0.5, 1.5
225 Al, Pb, Si, Sn, Cu 85, 8.5, 4, 1.5, 0.5
226 Al, Si, Cu 88, 11, 1
227 Al, Sn, Cu 79, 20, 1
228 Al, Cu, Sn, Pb 87, 5, 4, 4 2,300 23 137
229 Sb 6,643 631 9 18 0.0
230 Be,Co,Ni,Cu 1.8,,.2,99.5 8,304 982 17 121 0.0
231 Be,Co,Ni,Cu 1.8,,.2,99.5 8,304 982 17 121
232 Cu,Sn,Pb,Zn 83,7,7,3 8,857 1,038 10 58
TABLE 15.1 Tribomaterials Database (Part D)
Resistivity (u-ohm-cm) Hardness
Tensile Strength (MPa)
Youngs Modulus (MPa)
Fracture Toughness (MPa-m1/2) Data Source
Wear Coefficient
Maximum Operating Temperature (C)
Wear Rate (mm3/m)
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 1.5E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 9.8E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 5.9E-08 200 7.6E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 6.1E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 7.4E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 5.0E-09 200 4.0E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 1.0E-09 200 1.5E-08
217 HV 751 Glaeser 760
20 62 HRC 1,640 199,000 Hughes/Rowe 3.0E-07 200 2.4E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 5.0E-09 200 3.8E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-09 200 1.4E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-09 200 1.5E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 8.6E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 9.0E-08 200 9.4E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 9.0E-08 200 7.3E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-09 200 1.4E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 5.9E-08
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-08 200 1.6E-07
20 62 HRC 1,640 199,000 Hughes/Rowe 2.0E-10 200 1.7E-09
20 62 HRC 1,640 199,000 Hughes/Rowe 2.4E-07 200 1.5E-06
20 62 HRC 1,640 199,000 Hughes/Rowe 5.0E-09 200 5.9E-08
330 HV 1,000 125 Glaeser 760
20 62 HRC 1,640 199,000 Hughes/Rowe 1.2E-07 200 9.5E-07
413 HV 1,379 199,000 Glaeser 260
617 HV 2,041 207,000 Glaeser
20 694 HV 1,241 207,000 Glaeser
200 HV 689 207,000 Glaeser 260
20 225 HV 689 207,000 Glaeser 260
28 230 HV 758 207,000 38 Glaeser
18 224 HV 820 207,000 Glaeser
20 200 HV 689 207,000 Glaeser
200 HV 689 199,000 Glaeser 260
18 404 HV 1,303 207,000 Glaeser
695 HV 290,000 Glaeser
30 180 HV 607 207,000 77 Glaeser
195 HV 641 207,000 Glaeser
28 424 HV 1,379 207,000 77 Glaeser
20 62 HRC 1,640 199,000 Hughes/Rowe 8.0E-08 200 9.5E-07
14 210 HV 758 207,000 Glaeser
14 140 HV 448 207,000 Glaeser
30 789 HV 1,296 207,000 33 Glaeser
30 350 HV 1,723 207,000 Glaeser 260
310 HV 689 207,000 Glaeser
28 435 HV 1,420 207,000 Glaeser
28 740 HV 207,000 Glaeser
20 62 HRC 1,640 199,000 Hughes/Rowe 4.0E-09 200 5.9E-08
30 260 HV 979 207,000 20 Glaeser 260
19 540 HV 896 207,000 Glaeser
19 150 HV 552 207,000 55 Glaeser 8.0E-03 2.0E-02
200 HV 689 199,000 Glaeser 260
765 HV 2,758 207,000 Glaeser 3.1E-05 538 3.0E-05
60 HRC 1,930 207,000 ASTM G2,RR6,6/6/78,,9 labs,n=40 4.0E-04 8.0E-03
760 HV 2,758 202,000 Glaeser 427
18 160 HV 683 202,000 Glaeser 427
50 HRC 207,000 ASTM G2,RR11,7/13/83,10 labs,n=50 2.0E-03 538 3.9E-02
590 HV 1,930 207,000 60 Glaeser 3.0E-05 4.4E-05
60 HRC 1,930 207,000 ASTM G2,RR6,6/26/80,6 labs,n=6 4.0E-04 8.3E-03
598 HV 2,068 207,000 275 Glaeser 8.0E-04 538 5.0E-04
8 80 HB 296 71,000 Glaeser
5 15 HV 52 130,340 Glaeser
145 HV 310 82,000 Glaeser
3 30 HV 90 130,044 Glaeser 149
Booser 150
12 165 HV 448 79,300 Glaeser 260
12 100 HV 358 79,300 Glaeser 1.0E-04 260 1.1E-03
23 180 HB 621 124,000 Booser 260
10 70 HV 414 121,000 Glaeser 260
92 HRH 179 129,744 Booser 150
Booser 150
60 HB 179 Booser 150
35 HB 110 64,800 Booser 150
55 HRH 103 Booser 135
70 40 HV 10 78,332 Glaeser
5 393 HV 1,380 131,000 Glaeser 6.1E-05 427 6.1E-05
80 HV 483 131,000 Glaeser 427
80 HV 276 103,000 Glaeser 2.0E-04 149 3.0E-03
TABLE 15.1 Tribomaterials Database (Part C)
Number Component NamesComponent
Weight PercentDensity (kg/m3)
Melting Point (C)
Expansion Coefficient (µm/m)
Thermal Conductivity (watt/m/C)
Heat Capacity (kJ/kg C)
233 Cu,Sn,Pb 65,.5,34.5 9,134 20 294
234 Cu,Pb,Sn 70,25,5 9,300 925 19 63 0.0
235 Cu,Sn,Pb 80,10,10 8,857 1,038 19 47
236 Cu, Sn, c 89, 10,1 6,600 17 29
237 Fe, Cu, Sn, C 59, 36, 4, 1 6,200 13 31
238 Cd 8,664 321 31 92 0.0
239 Cd, Ni 98.5, 1.5 8,600 31 92
240 Al, Sn, Cu, Ni 91, 6.5, 1, 1 2,900 24 206
241 Cu 99.94 9,134 1,083 17 393 0.0
242 Cu, Pb 70, 30 9,000 985
243 Cu, Pb 65, 35 9,000 955 294
244 P,Ni 1-12,88-99 8,027 12 4
245 P,Ni 1-12,88-99 8,027 12 4
246 Au 32,692 1,064 14 294 0.0
247 Cu, Sn, Zn 88, 10, 2 8,700 975 20 74
248 C,W,Fe,Cr,Mo,Va,Mn,Si,Ni .15,4,6,16,17,.3,1,1,54.6 8,860 1,304 13 135 0.0
249 C,Si,Mn,Cu,Ni,Cr,Co,Mo,Al,Ti,Fe .1,.75,.5,.75,50,18,5,3,.8,1,20 8,027 1,370 13 14 0.0
250 In 7,197 179 25 69 0.0
251 Pb 11,350 327 29 35 0.0
252 Pb,Sb,Sn,As,Cu 82.5,15,1,1,.6 10,200 281 25 24
253 Pb,Sb,Sn,As,Cu 83,10,6,.25,.5 10,800 240 24 0.0
254 Pb,Sb,Sn,As,Cu 75,15,10,.5,.5 9,688 240 12 24 0.0
255 Pb,Sb,Sn,As,Cu 80,15,5,.5,.5 10,520 24 0.0
256 Cu, Sn, Pb 88, 10, 2 8,800 975 18 69
257 Cu, Sn, Pb, Zn 85, 5, 5, 5 8,700 18 71
258 Cu, Sn, Pb 70, 5, 25 9,000 19 62
259 Al,Cu,Fe,Mn,Zn 5,63,3,3,25 7,833 923 22 35 0.0
260 C,Ti,Mo .02,.5,99.4 10,240 15 128 0.0
261 Ni,Al,Fe,Mn,C,Si,Ti,Cu 65,3,2,1.5,.25,1.0,.5,27 8,304 1,316 14 14 0.0
262 Cu, Sn, Zn 88, 8, 4 8,700 975 18 74
263 C,Mn,Si,Cr,Ni,Mo,Fe .12,2,1,16,25,6,49.9 8,027 16
264 C,Mn,Si,Cr,Ni,Mo,Fe .12,2,1,16,25,6,49.9 8,027 16
265 Cu, Sn, Pb 80, 10, 10 8,900 750 19 47
266 Cu,Sn,P 95.6,4.2,.2 8,857 1,060 18 84 0.0
267 Cu, Sn, Pb 78, 6, 16 9,200 19 52
268 Cu,Si,Sn,Zn,Fe,Al,Mn 87,4,1,4,2,1,1 8,359 971 17 28 0.0
269 Ag 10,520 961 19 415 0.0
270
271 Cr,C,Si,Mo,Fe,Ni,W,Co 30,2.5,1,1,3,3,12,47.5 9,134
272 C,Mn,Si,Fe,Ni,Cr,W,Co 1.4,1,1.5,3,3,31,5,54 8,304 1,275 176
273 9,000
274 C,Mn,SI,Fe,Ni,Cr,W,Co 2.5,1,1,3,2.5,32,17,41 8,857 14
275
276
277 C,Si,Fe,Ni,Cr,W,Co 1.2,1.2,1,1,30,5,60.5 8,304 14
278 C,Al,V,Ti .1,6,4,90 4,429 1,600 9 7 1.0
279 C,Al,V,Ti .1,6,4,90 4,429 9 7 1.0
280 SN 7,307 231 24 64 0.0
281 Sn,Sb,Cu 84,8,8 7,470 420
282 Sn,Sb,Cu 89,7.5,3.5 7,473 241 23 52
283 Sn,Sb,Cu 91,4.5,4.5 7,473 273 54.0
284 Sn, Sb, Cu 86, 7.5, 6.5
285 Co,Mo,Cr,Si,C 52,28,17,3,.08 8,664 1,288 19 171
286 Co,Mo,Cr,Si,C 62,28,8,2,.08 9,134 1,288 18 176
287 Ni,Mo,Cr,Si,C 50,32,15,3,.08 8,857 1,243 136
288 Ni,Cu,W 7,3,90 17,000 3,410 7 167
289 Si,Zn,Cu,Fe,Ti,Mn,Ni,Mg,Va 22,.1,1.5,.75,.15,.1,2.2,1,.1 2,768 538 16 126 1.0
290 C,Mn,Si,Cr,Ni,Mo,Co,Ti,Al,Zr .1,.5,.75,20,57,4,13,3,1,.1 8,138 14 12
291 C,Mn,Si,Cr,Ni,Mo,Co,Ti,Al,Zr .1,.5,.75,20,57,4,13,3,1,.1 8,138 14 12 1.0
292 Ni,Pb,Sn,Zn,Mn 80,4,8,7,1 8,857 5 26
293 Zn 7,141 419 31 112 0.0
294 Zn,Al,Cu,Mg 88.2,11,.75,.02 6,089 404 28 115
295 Zn,Al,Cu,Mg 70.8,27,2.2,.015 4,982 427 12 124
296 Sn,Fe,Cr,Ni,Zr 1.5,.1,.1,.05,98.4 6,700 7 15
297 1,410 85 0.0 2.0
298 1,050 90
299
300 PTFE-40 % ceramic fibre filled 1,900 18 0.0 1.0
301 fluorinated ethylene propylene 2,140 180 0.0 1.0
302 polyphenylene sulfide resin, fibrefilled 1,661 22
303 polyamide 1,130 80 0.0 2.0
304 polyamide 1,107 0.0
305 1,140 81 0.0 2.0
306 polyamide 1,384 29 0.0 1.0
307 1,200 67 0.0
308 1,310 258 95 0.0
309 940 104 110 0.0 1.0
310 1,430 49 0.0 1.0
TABLE 15.1 Tribomaterials Database (Part D)
Resistivity (u-ohm-cm) Hardness
Tensile Strength (MPa)
Youngs Modulus (MPa)
Fracture Toughness (MPa-m1/2) Data Source
Wear Coefficient
Maximum Operating Temperature (C)
Wear Rate (mm3/m)
28 HV 59 64,688 Glaeser 176
48 HV 186 129,744 Glaeser 1.0E-04 2.1E-03
60 HV 207 129,528 Glaeser 121
40 HB 90 11,000 Booser 135
103 Booser 135
7 21 HV 69 65,440 Glaeser 3.0E-05 2.9E-03
35 HB 65,440 Booser 260
45 HB 138 129,044 Booser 150
2 42 HV 193 103,000 Glaeser 1.0E-04 5.1E-03
28 HB 59 Booser 177
25 HB 55 Booser 177
90 1050 HV 200,000 Glaeser 320
90 500 HV 689 200,000 Glaeser 320
2 35 HV 138 74,500 Glaeser
75 HB 310 103,000 Booser 260
140 216 HV 551 197,000 Glaeser
13 410 HV 1,380 200,000 96 Glaeser 649
9 1 HV 3 11,000 Glaeser
24 14 HV 41 13,800 Glaeser
20 HV 69 29,000 Glaeser 204
20 HV 69 29,000 Glaeser 232
22 HV 69 29,000 Glaeser 232
11 HV 69 29,000 Glaeser 232
77 HB 290 130,560 Booser 260
60 HB 241 64,764 Booser 232
48 HB 186 62,204 Booser 204
7 225 HV 793 131,068 Glaeser
264 HV 689 324,000 Glaeser 538
50 320 HV 689 179,000 Glaeser 538
70 HB 310 96,500 Booser 260
320 HV 1,103 197,000 Glaeser 649
202 HV 827 197,000 Glaeser 649
4 60 HB 241 64,744 Booser 232
9 145 HV 552 110,000 Glaeser
57 HB 214 129,744 Booser 232
85 HV 310 103,000 Glaeser
2 34 HV 207 71,000 Glaeser 4.0E-03 204 2.4E-01
52 HRC ASTM G2,RR2,12/9/75,5 labs,n=5 2.0E-04 4.4E-03
562 HV 241,000 Glaeser 6.1E-05 9.8E-04
91 395 HV 834 210,000 Glaeser 1.0E-03 1.1E-03
383 HV 12 Glaeser 1.5E-05 9.7E-04
675 HV 517 255,000 Glaeser 649
52 HRC ASTM G2,RR5,3/7/78,8 labs,n=38 2.0E-04 3.8E-03
52 HRC ASTM G2,RR1,5/23/75,3 labs,n=3 1.0E-04 3.4E-03
526 HV 689 207,000 Glaeser
171 301 HV 896 110,000 71 Glaeser 400
171 1700 HV 110,000 Glaeser 400
12 8 HV 15 41,400 Glaeser
26 HV 81 51,000 Glaeser 220
24 HV 81 64,688 Glaeser 238
17 HV 81 64,764 Glaeser 221
26 HB 117 Booser 150
739 HV 241,000 Glaeser 1.0E-04 704 5.5E-03
655 HV 689 269,000 Glaeser 7.0E-05 704 1.4E-03
485 HV 214,000 Glaeser 7.0E-06 649 2.4E-04
6 257 HV 689 276,000 Glaeser
140 HV 276 93,000 Glaeser 260
157 HV 827 211,000 Glaeser 871
373 HV 1,280 211,000 Glaeser 871
165 HV 586 159,000 Glaeser 649
6 47 HV 103 130,340 Glaeser 5.0E-02 2.3E+00
28 93 HV 296 82,940 21 Glaeser 121
30 107 HV 414 129,528 21 Glaeser 149
74 185 HV 517 129,528 Glaeser 400
80 HRM 61 2,550 Booser 93
103 HRR 55 2,760 Booser 82
Glaeser
5.48E+11 5 HV 18 13,800 Glaeser 260
5 HV 21 689 Glaeser 204
15 HV 69 11,000 Glaeser 204
4.01E+19 15 HV 80 3,700 Glaeser 85
55 2,070 Glaeser 60
5.02E+12 121 HRR 81 2,830 Booser 88
1.00E+11 115 HV 62 6,890 Glaeser 121
2.80E+14 66 HRM 62 2,280 Booser 116
7.15E+16 70 HRM 59 2,340 Booser 149
1.00E+15 65 HRR 28 965 Booser 82
1.00E+13 52 HRE 90 3,170 Booser 316
TABLE 15.1 Tribomaterials Database (Part C)
Number Component NamesComponent
Weight PercentDensity (kg/m3)
Melting Point (C)
Expansion Coefficient (µm/m)
Thermal Conductivity (watt/m/C)
Heat Capacity (kJ/kg C)
311 polyimide filled, self lubricating 1,520 8
312 1,060 59
313 1,340 54 0.0 1.0
314 910 160 72 0.0 1.0
315 1,240 56 0.0 0.0
316 1,250 72 0.0
317 2,180 55 0.0 1.0
318 graphite, PTFE, polyamide/imide 12, 3, 85 1,460 25 1.0
319 ultra high molecular weight polyethylene 930 200 0.0 2.0
320 1,200 77 0.0 2.0
321 carbon fiber, acetal 20, 80 1,460 40
322 glass fiber, acetal 30, 70 1,630 43
323 PTFE, acetal 15, 85 1,490 94
324 silicone, acetal 2, 98 1,400 90
325 PTFE, ABS 15, 85 1,140 94
326 cellulose 1,200 52
327 carbon fiber, nylon 6/6 20, 80 1,230 25
328 glass fiber, nylon 6/6 30, 70 1,370 32
329 PTFE, nylon 6/6 20, 80 1,260 83
330 silicone, nylon 6/6 2, 98 1,120 81
331 polyetheretherketone 1,430 334 20
332 cotton laminate 1,330 22
333 wood flour 1,400 40 0.0
334 carbon fiber, polycarbonate 30, 70 1,330 16
335 glass fiber, polycarbonate 30, 70 1,430 23 0.0
336 PTFE, polycarbonate 15, 85 1,280 70
337 carbon fiber, polyester 30, 70 1,410 9
338 glass fiber, polyester 30, 70 1,520 22 0.0
339 PTFE, polyester 20, 80 1,440 99
340 silicone, polyester 2, 98 1,290 95
341 PTFE, polyethylene 20, 80 1,080 128
342 glass fiber, polyimide 1,900 14
343 graphite, polyimide 15, 85 1,510 49 1.0
344 glass fiber, polyphenylene oxide 30, 70 1,280 25
345 PTFE, polyphenylene oxide 15, 85 1,150 63
346 carbon fiber, polyphenylene sulfide 30, 70 1,450 11
347 glass fiber, polyphenylene sulfide 40, 60 1,650 27 0.0 1.0
348 PTFE, polyphenylene sulfide 20, 80 1,450 59
349 PTFE, polypropylene 20, 80 1,020 76
350 carbon fiber, polysulfone 30, 70 1,370 11
351 glass fiber, polysulfone 30, 70 1,450 25 0.0
352 PTFE, polysulfone 15, 85 1,320 59
353 glass fiber, polyurethane 30, 70 1,460 45
354 PTFE, polyurethane 15, 85 1,330
355 fabric, PTFE 2,500 0.0
356 glass fiber, PTFE 15, 85 2,190 121 0.0
357 graphite, PTFE 15, 85 2,080 126 1.0
358 mineral filled PTFE
359 polyphenylene sulfide resin 1,661 0.0
360 graphite, polyimide 15, 85 1,384 63 1.0
361 polyimide, graphite 40, 60 1,384 23
362 Isobutylene-isoprene 830 10 0.0
363 chloroprene 1,107 32 0.0
364 butadiene-acrylonitrile 1,107 16 0.0
365 polysiloxane 1,384 25 0.0
366 disocyanate polyester 1,107 125 0.0 2.0
367 vinylidene fluoride-hexafluoropropylene 1,500
368 PTFE - Glass woven fabric 23 0.0
TABLE 15.1 Tribomaterials Database (Part D)
Resistivity (u-ohm-cm) Hardness
Tensile Strength (MPa)
Youngs Modulus (MPa)
Fracture Toughness (MPa-m1/2) Data Source
Wear Coefficient
Maximum Operating Temperature (C)
Wear Rate (mm3/m)
56 10,400 Glaeser 288
66 2,480 Booser 116
76 4,140 Booser 188
1.00E+17 95 HRR 35 1,240 Booser 77
5.00E+16 70 2,690 Booser 171
1.00E+12 14 103 Booser 110
1.00E+17 60 SHORE D 23 620 Booser 260
8.03E+13 40 HV 164 6,600 Glaeser 260
5.01E+14 50 HV 41 689 Glaeser 77
1.70E+16 65 SHORE A 16 41 Booser 66
81 9,310 Booser
118 HRR 135 8,960 Booser
48 2,070 Booser
55 2,410 Booser 93
45 2,550 Booser
95 HRM 90 2,410 Booser 149
193 16,600 Booser 138
179 8,960 Booser 138
62 2,550 Booser 88
75 2,760 Booser 88
207 17,000 Glaeser 220
105 HRM 69 Booser 138
85 HRE 48 827 Booser 138
166 13,100 Booser 116
118 HRR 128 8,270 Booser 116
48 2,070 Booser 116
152 15,900 Booser 204
100 HRM 138 8,270 Booser 204
45 1,720 Booser 149
55 2,280 Booser 149
26 896 Booser 82
120 HRM 186 Booser 316
88 HRM 66 3,790 Booser 316
128 7,930 Booser 127
55 2,280 Booser 116
186 32,260 Booser 188
5.56E+14 123 HRR 159 12,400 Booser 188
59 3,790 Booser 188
28 1,170 Booser 77
159 14,100 Booser 171
124 8,270 Booser 171
54 2,620 Booser 171
57 1,310 Booser 110
12 97 Booser 110
Booser 204
1,100 Booser 260
20 1,380 Booser 260
Glaeser
131 11,700 Glaeser 260
1.40E+14 5068 HV 83 3,450 Glaeser 371
1.00E+12 35 HV 62 4,140 Glaeser 371
2 HV 21 Glaeser 149
2 HV 21 Glaeser 116
3.50E+10 2 HV 21 Glaeser 149
1.40E+14 3 HV 7 Glaeser 316
2.00E+11 6 HV 34 Glaeser 116
2.00E+12 3 HV 14 Glaeser 232
Glaeser 204
TABLE 15.1 Tribomaterials Database (Part E)
NumberP*V Limit (MPa*m/s)
Maximum Pressure (MPa)
Wear Constant (mm3/mm*N)
Friction Coefficent
Maximum Velocity (m/s)
Contact Geometry
Load (N)
Temp. (C)
Velocity (m/s)
Distance (m)
Specimen Shape
1
2
3
4
5
6
7
8 2.0E-10 PIN-ON-RING 3.9 1.8 1.0E+04 PIN
9
10
11
12 0.25
13
14
15
16 83
17 207 6.0E-09 0.15 RING-ON-RING 37 2.7 1.1E+07 RING
18 0.35 3.0E-09 PIN-ON-CYLINDER PIN
19 0.7 2.0E-09 2.5 PIN-ON-CYLINDER PIN
20 0.7 1.0E-09 0.16 PIN-ON-CYLINDER PIN
21 0.7 PIN-ON-CYLINDER PIN
22 PIN-ON-CYLINDER PIN
23 0.53 6.0E-10 0.16 2.5 PIN-ON-CYLINDER PIN
24 0.7 4.0E-09 PIN-ON-CYLINDER PIN
25
26
27
28
29
30
31
32 0.012
33
34
35 0.17
36
37
38
39
40 0.42 13.8
41
42 1.75 41 0.1
43
44 4.0E-09 BLOCK-ON-RING 124 24 2.4 4250 BLOCK
45
46
47
48
49
50
51
52 1.75 14.5 2.3
53
54 1.23 27.6 1.1
55 1.05 51.7
56 1.05 20.7 2
57 1.38 7.0E-06
58
59
60
61
62 4.0E-09 BLOCK-ON-RING 9.8 1 3.6E+06 BLOCK
63
64 2.0E-09 BLOCK-ON-RING 657 0.05 1.2 BLOCK
65
66
67 3.0E-07 BLOCK-ON-RING 45 24 2.4 4310 BLOCK
68 4.0E-07 BLOCK-ON-RING 45 24 2.4 4250 BLOCK
69 2.0E-07 BLOCK-ON-RING 45 24 2.4 4280 BLOCK
70 6.0E-07 BLOCK-ON-RING 130 24 2.4 1440 BLOCK
71
72
73
74
75 5.0E-09 BLOCK-ON-RING 657 0.05 1.2 BLOCK
76 4.0E-13 FOUR BALL 60 50 0.58 2100 BALL
77 1.0E-12 FOUR BALL 60 50 0.58 2100 BALL
78 4.0E-11 FOUR BALL 60 50 0.58 2100 BALL
TABLE 15.1 Tribomaterials Database (Part F)
Contact EnvironmentStandard
TestCounterface
MaterialCounterface Description
Wear Type
AIR
AIR TUNGSTEN CARBIDE ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CAST IRON ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL
AIR CARBON STEEL ADHESIVE
AFS 50/70 sand; 471 g/min CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
AIR CARBON STEEL
Boundary lubricated, oil-filled material CARBON STEEL LUBRICATED
Boundary lubricated, oil-filled material CARBON STEEL LUBRICATED
Boundary lubricated, oil-filled material CARBON STEEL LUBRICATED
Boundary lubricated, oil-filled material CARBON STEEL LUBRICATED
AIR CARBON STEEL ADHESIVE
AIR MILD STEEL ADHESIVE
AIR M2 TOOL STEEL ADHESIVE
AFS 50/70 sand; 435 g/min CHLOROBUTYL A57 SHORE HARDNESS ABRASIVE
AFS 50/70 sand; 471 g/min CHLOROBUTYL A59 SHORE HARDNESS ABRASIVE
AFS 50/70 sand; 234 g/min ASTM G65-D CHLOROBUTYL A62 SHORE HARDNESS ABRASIVE
AFS 50/70 sand; 329 g/min; 49% RH ASTM G65-B CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
AIR M2 TOOL STEEL ADHESIVE
Paraf.Oil;[email protected];Addit:DibutylPhosphate;Cyclohexyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:DibutylPhosphate;Benzyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected] STEEL 52100 STEEL LUBRICATED
TABLE 15.1 Tribomaterials Database (Part E)
NumberP*V Limit (MPa*m/s)
Maximum Pressure (MPa)
Wear Constant (mm3/mm*N)
Friction Coefficent
Maximum Velocity (m/s)
Contact Geometry
Load (N)
Temp. (C)
Velocity (m/s)
Distance (m)
Specimen Shape
79 4.0E-12 FOUR BALL 60 50 0.58 2100 BALL
80 3.0E-12 FOUR BALL 60 50 0.58 2100 BALL
81 1.0E-12 FOUR BALL 60 50 0.58 2100 BALL
82 2.0E-11 FOUR BALL 60 50 0.58 2100 BALL
83 2.0E-11 FOUR BALL 60 50 0.58 2100 BALL
84 3.0E-11 FOUR BALL 60 50 0.58 2100 BALL
85 1.0E-07 BLOCK-ON-RING 130 24 2.4 4310 BLOCK
86 6.0E-07 BLOCK-ON-RING 130 24 2.4 1440 BLOCK
87 3.0E-11 FOUR BALL 60 50 0.58 2100 BALL
88 3.0E-11 FOUR BALL 60 50 0.58 2100 BALL
89 5.0E-13 FOUR BALL 60 50 0.58 2100 BALL
90 2.0E-13 FOUR BALL 60 50 0.58 2100 BALL
91 1.0E-10 FOUR BALL 60 50 0.58 2100 BALL
92 6.0E-11 FOUR BALL 60 50 0.58 2100 BALL
93 5.0E-13 FOUR BALL 60 50 0.58 2100 BALL
94 4.0E-13 FOUR BALL 60 50 0.58 2100 BALL
95 6.0E-13 FOUR BALL 60 50 0.58 2100 BALL
96 6.0E-12 FOUR BALL 60 50 0.58 2100 BALL
97 1.0E-11 FOUR BALL 60 50 0.58 2100 BALL
98 3.0E-12 FOUR BALL 60 50 0.58 2100 BALL
99 9.0E-13 FOUR BALL 60 50 0.58 2100 BALL
100 2.0E-12 FOUR BALL 60 50 0.58 2100 BALL
101 1.0E-11 FOUR BALL 60 50 0.58 2100 BALL
102 1.0E-12 FOUR BALL 60 50 0.58 2100 BALL
103 5.0E-13 FOUR BALL 60 50 0.58 2100 BALL
104 5.0E-13 FOUR BALL 60 50 BALL
105 4.0E-11 FOUR BALL 60 50 BALL
106 3.0E-11 FOUR BALL 60 50 0.58 2100 BALL
107 2.0E-07 BLOCK-ON-RING 45 24 2.4 4310 BLOCK
108 2.0E-11 FOUR BALL 60 50 0.58 2100 BALL
109 6.0E-12 FOUR BALL 60 50 0.58 2100 BALL
110 4.0E-12 FOUR BALL 60 50 0.58 2100 BALL
111 2.0E-11 FOUR BALL 60 50 0.58 2100 BALL
112 1.0E-07 FOUR BALL 60 50 BALL
113 3.0E-14 FOUR BALL 60 50 BALL
114 3.0E-11 FOUR BALL 60 50 0.58 2100 BALL
115 3.0E-11 FOUR BALL 60 50 0.58 2100 BALL
116 1.0E-06 FOUR BALL 60 50 BALL
117 3.0E-12 FOUR BALL 60 50 0.58 2100 BALL
118 5.0E-13 FOUR BALL 60 50 0.58 2100 BALL
119 1.0E-09 FOUR BALL 60 50 BALL
120 1.0E-11 FOUR BALL 60 50 0.58 2100 BALL
121 1.0E-11 FOUR BALL 60 50 0.58 2100 BALL
122 2.0E-12 FOUR BALL 60 50 0.58 2100 BALL
123 4.0E-13 FOUR BALL 60 50 0.58 2100 BALL
124 4.0E-13 FOUR BALL 60 50 0.58 2100 BALL
125 7.0E-12 FOUR BALL 60 50 0.58 2100 BALL
126 4.0E-11 FOUR BALL 60 50 0.58 2100 BALL
127 3.0E-13 FOUR BALL 60 50 0.58 2100 BALL
128 5.0E-13 FOUR BALL 60 50 0.58 2100 BALL
129 2.0E-07 BLOCK-ON-RING 45 24 2.4 4310 BLOCK
130 6.0E-13 FOUR BALL 60 50 0.58 2100 BALL
131 4.0E-12 FOUR BALL 60 50 0.58 2100 BALL
132 9.0E-13 FOUR BALL 60 50 0.58 2100 BALL
133 8.0E-12 FOUR BALL 60 50 0.58 2100 BALL
134 3.0E-13 FOUR BALL 60 50 0.58 2100 BALL
135 5.0E-11 FOUR BALL 60 50 0.58 2100 BALL
136 1.0E-11 FOUR BALL 60 50 0.58 2100 BALL
137 5.0E-11 FOUR BALL 60 50 0.58 2100 BALL
138 3.0E-11 FOUR BALL 60 50 0.58 2100 BALL
139 6.0E-12 FOUR BALL 60 50 0.58 2100 BALL
140 8.0E-13 FOUR BALL 60 50 0.58 2100 BALL
141 4.0E-13 FOUR BALL 60 50 0.58 2100 BALL
142 1.0E-11 FOUR BALL 60 50 0.58 2100 BALL
143 5.0E-11 FOUR BALL 60 50 0.58 2100 BALL
144 1.0E-12 FOUR BALL 60 50 0.58 2100 BALL
145 5.0E-13 FOUR BALL 60 50 0.58 2100 BALL
146 1.0E-11 FOUR BALL 60 50 0.47 1680 BALL
147 8.0E-14 FOUR BALL 60 50 0.47 1680 BALL
148 9.0E-11 FOUR BALL 60 50 0.58 2100 BALL
149 9.0E-11 FOUR BALL 60 50 0.58 2100 BALL
150 7.0E-12 FOUR BALL 60 50 0.47 1680 BALL
151 2.0E-13 FOUR BALL 60 50 0.56 2010 BALL
152 6.0E-13 FOUR BALL 60 50 0.56 2010 BALL
153 7.0E-12 FOUR BALL 60 50 0.47 1680 BALL
154 7.0E-13 FOUR BALL 60 50 0.56 2010 BALL
155 6.0E-13 FOUR BALL 60 50 0.56 2010 BALL
TABLE 15.1 Tribomaterials Database (Part F)
Contact EnvironmentStandard
TestCounterface
MaterialCounterface Description
Wear Type
Paraf.Oil;[email protected];Addit:Phosphate ;Diethyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphate ;Di-n-butyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphate ;Di-n-dodecyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Di-n-Dodecyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;Butyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Mineral Oil;[email protected] STEEL 52100 STEEL LUBRICATED
AFS 50/70 sand; 380 g/min ASTM G65-A CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
AFS 50/70 sand; 323 g/min ASTM G65-B CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
Paraf.Oil;[email protected];Addit:Disulfide;Di-(para-t-nonylphenyl);18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Di-n-Octyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Dibuytlphoshoramidate;n-Butyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:DibutylPhosphate;n-Octyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Diethyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Di-n-Butyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphate ;Di-2-ethylhexyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:DibutylPhosphate;2-Ethylhexyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Di2EthylhexylPhosphate;Benzyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphate ;Tributyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Di-n-Hexadecyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Di2EthylhexylPhosphate;Methyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;Lauryl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Min.Oil;[email protected];Addit:Dibuytlphoshoramidate;Ethyl,Ethyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Diesterdisulfide;[-SCH2COOC2H5]2;2.3mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Dibuytlphoshoramidate;Phenyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Min.Oil;[email protected];Addit:Dibuytlphoshoramidate;t-Butyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
paraffin oil;tricresyl phosphate STEEL 52100 STEEL LUBRICATED
paraffinic oil STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Di2EthylhexylPhosphate;n-Octyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
AFS 50/70 sand; 239 g/min ASTM G65-D CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
Par.Oil;[email protected];Add:Diesterdisulfide;[-S(CH2)2COOC2H5]2;2.3mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Di2EthylhexylPhosphate;n-Butyl NH2;4mmol/100g STEEL 52100 STEEL LUBRICATED
Par.Oil;[email protected];Add:Di2EthylhexylPhosphate;n-PropylNH2;4mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Di-(para-t-butylphenyl);18 mmol/100g STEEL 52100 STEEL LUBRICATED
dry air STEEL 52100 STEEL LUBRICATED
Formulated Engine Oil STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;Ethyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected] STEEL 52100 STEEL LUBRICATED
dry argon STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Di2EthylhexylPhosphate;Ethyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Par.Oil;[email protected];Add:Di2EthylhexylPhosphate;CyclohexylNH2;4mmol/100g STEEL 52100 STEEL LUBRICATED
Cyclohexane STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Di2EthylhexylPhosphate;Dodecyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Par.Oil;[email protected];Add:Di2EthylhexylPhosphate;2-EthylhexylNH2;4mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;2-Ethylhexyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphate ;Tricresyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Min.Oil;[email protected];Addit:Dibuytlphoshoramidate;Ethyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Di-n-Octadecyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected] STEEL 52100 STEEL LUBRICATED
Min.Oil;[email protected];Addit:Dibuytlphoshoramidate;n-Dodecyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Dibuytlphoshoramidate;n-Dodecyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
AFS 50/70 sand; 380 g/min ASTM G65-D CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
Paraf.Oil;[email protected];Addit:Dibuytlphoshoramidate;Allyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;Ethyl,Benzyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;Ethyl,o-Nitrophenyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Diphenyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Min.Oil;[email protected];Addit:Dibuytlphoshoramidate;Octadecyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Par.Oil;[email protected];Add:Disulfide;Di-2,4,4Trimethylpentyl;18mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Dibenzyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Di-t-Octyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Dicyclohexyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;Butyl,Phenyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;Cyclohexyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Min.Oil;[email protected];Add:Dibuytlphoshoramidate;n-Octyl,n-Octyl;4mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphonate;Butyl,Hexyl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Disulfide;Di-2-Ethylhexyl;18 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Phosphate ;Dilauryl;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:DibutylPhosphate;Dodecyl NH2;4 mmol/100g STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:1-Chloro Hexadecane;2.0 Wt% STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Tricresyl Phosphate + Oleic Acid;1.5+1.5 Wt% STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Diesterdisulfide;[-S(CH2)3OC2H5]2;2.3mmol/100g STEEL 52100 STEEL LUBRICATED
Paraf.Oil;[email protected];Addit:Diesterdisulfide;[-S(CH2)2OC2H5]2;2.3mmol/100g STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Antimony Diakyldithiocarbamate;2.0 Wt% STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphos'o-dithioate;Isopropyl/p-Octylphenyl;.056Wt%P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;Isobutyl/Pentyl;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Lead Naphthenate;1.0 Wt% STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;C6-C10;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;2-Ethylhexyl;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
TABLE 15.1 Tribomaterials Database (Part E)
NumberP*V Limit (MPa*m/s)
Maximum Pressure (MPa)
Wear Constant (mm3/mm*N)
Friction Coefficent
Maximum Velocity (m/s)
Contact Geometry
Load (N)
Temp. (C)
Velocity (m/s)
Distance (m)
Specimen Shape
156 3.0E-11 FOUR BALL 60 50 0.58 2100 BALL
157 2.0E-11 FOUR BALL 60 50 0.58 2100 BALL
158 7.0E-12 FOUR BALL 60 50 0.58 2100 BALL
159 1.0E-11 FOUR BALL 60 50 0.58 2100 BALL
160 8.0E-13 FOUR BALL 60 50 0.56 2010 BALL
161 7.0E-13 FOUR BALL 60 50 0.56 2010 BALL
162 2.0E-13 FOUR BALL 60 50 0.56 2010 BALL
163
164 4.0E-12 FOUR BALL 60 50 0.58 2100 BALL
165 6.0E-13 FOUR BALL 60 50 0.56 2010 BALL
166 5.0E-13 FOUR BALL 60 50 0.56 2010 BALL
167 2.0E-13 FOUR BALL 60 50 0.56 2010 BALL
168 2.0E-13 FOUR BALL 60 50 0.56 2010 BALL
169 1.0E-11 FOUR BALL 60 50 0.47 1680 BALL
170 1.0E-11 FOUR BALL 60 50 0.47 1680 BALL
171 1.0E-11 FOUR BALL 60 50 0.47 1680 BALL
172 2.0E-13 FOUR BALL 60 50 0.56 2010 BALL
173 5.0E-13 FOUR BALL 60 50 0.56 2010 BALL
174 3.0E-12 FOUR BALL 60 50 0.47 1680 BALL
175 3.0E-14 FOUR BALL 60 50 0.47 1680 BALL
176 2.0E-11 FOUR BALL 60 50 0.47 1680 BALL
177 7.0E-13 FOUR BALL 60 50 0.56 2010 BALL
178
179 1.0E-11 FOUR BALL 60 50 0.56 2010 BALL
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194 1.0E-11 FOUR BALL 60 50 0.47 1680 BALL
195
196
197
198
199
200
201
202 5.0E-13 FOUR BALL 60 50 0.58 2100 BALL
203
204
205 5.0E-06 PIN-ON-RING 3.9 1.8 1.0E+04 PIN
206
207 3.0E-09 BLOCK-ON-RING 9.8 1 3.6E+06 BLOCK
208 6.0E-08 BLOCK-ON-RING 130 24 2.4 4.3E+03 BLOCK
209
210
211 3.0E-07 BLOCK-ON-RING 130 24 2.4 1.4E+03 BLOCK
212 4.0E-09 BLOCK-ON-RING 9.8 1 3.6E+06 BLOCK
213 6.0E-08 BLOCK-ON-RING 130 24 2.4 4.3E+03 BLOCK
214 2.0E-07 PIN-ON-RING 3.9 1.8 1.0E+04 PIN
215
216
217
218
219 34.5
220
221 206 1.0E-07 BLOCK-ON-RING 9.8 1 3.6E+06 BLOCK
222 41.4 3.0E-07 0.46
223
224 34.5
225 34.5
226 34.5
227 34.5
228 1.75 13.8 6.1
229
230 344 1.0E-08 PIN-ON-RING 3.9 1.8 1.0E+04 PIN
231
232 17 3.0E-07 BLOCK-ON-RING 9.8 1 3.6E+06 BLOCK
TABLE 15.1 Tribomaterials Database (Part F)
Contact EnvironmentStandard
TestCounterface
MaterialCounterface Description
Wear Type
Par.Oil;[email protected];Add:Diesterdisulfide;[-S(CH2)10COOC2H5]2;2.3mmol/100g STEEL 52100 STEEL LUBRICATED
Par.Oil;[email protected];Add:Diesterdisulfide;[-S(CH2)2COOC10H21]2;2.3mmol/100g STEEL 52100 STEEL LUBRICATED
Par.Oil;[email protected];Add:Diesterdisulfide;[-S(CH2)3COOC2H5]2;2.3mmol/100g STEEL 52100 STEEL LUBRICATED
Par.Oil;[email protected];Add:Diesterdisulfide;[-S(CH2)5COOC2H5]2;2.3mmol/100g STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;1-Methylheptyl;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;n-Butyl;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;Isobutyl;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
Paraffin Oil;[email protected] STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;2,2-Dimenthylpnetyl;0.12Wt%P STEEL 52100 STEEL LUBRICATED
Min.Oil;Add:ZnDialkylphos'o-dithioate;2-Ethylhexyl/p-Octylphenyl;.056Wt%P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;p-Octylphenyl;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphos'o-dithioate;Isobutyl/p-Octylphenyl;.056Wt%P STEEL 52100 STEEL LUBRICATED
Mineral Oil STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Hexachloro-1, 3-Butandiene;2.0 Wt% STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Oleic Acid;2.0 Wt% STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;Isopropyl;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;n-Dodecyl;0.12 Wt% P STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Tricresyl Phosphate;1.5 Wt% STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Zinc 0, 0-Dialkylphosphorodithioate;2.0 Wt% STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Bis-(B-Chloroethyl) vinylphosphonate;1.0 Wt% STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:ZnDialkylphosphoro-dithioate;Sec-Butyl;0.056 Wt% P STEEL 52100 STEEL LUBRICATED
Mineral Oil STEEL 52100 STEEL LUBRICATED
Min.Oil;Addit:Perfluoroctanoic Acid;0.05 Wt% STEEL 52100 STEEL LUBRICATED
AIR
Paraf.Oil;[email protected];Addit:Phosphonate;Stearyl,H;4 mmol/100g STEEL 52100 STEEL LUBRICATED
AIR MILD STEEL ADHESIVE
AIR MILD STEEL ADHESIVE
AFS 50/70 sand; 353 g/min ASTM G65-A CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
AFS 50/70 sand; 324 g/min; 51% RH ASTM G65-B CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
AIR MILD STEEL ADHESIVE
AFS 50/70 sand; 300 g/min ASTM G65-A CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
AIR TOOL STEEL ADHESIVE
AIR CARBON STEEL
AIR MILD STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL
AIR CARBON STEEL
AIR CARBON STEEL
AIR CARBON STEEL
Boundary lubricated, oil-filled material CARBON STEEL LUBRICATED
AIR HARD STEEL ADHESIVE
AIR 440C STAINLESS STEEL ADHESIVE
TABLE 15.1 Tribomaterials Database (Part E)
NumberP*V Limit (MPa*m/s)
Maximum Pressure (MPa)
Wear Constant (mm3/mm*N)
Friction Coefficent
Maximum Velocity (m/s)
Contact Geometry
Load (N)
Temp. (C)
Velocity (m/s)
Distance (m)
Specimen Shape
233 14
234 2.0E-07 BLOCK-ON-RING 9.8 1 3.6E+06 BLOCK
235 10
236 1.75 13.8 6.1
237 1.23 17.2 4.1
238 1.0E-07 PIN-ON-RING 19.6 1.9 6.7E+04 PIN
239 13.8 2.0E-08
240 34.5
241 3.0E-07 PIN-ON-RING 19.6 0.13 9.7E+03 PIN
242 13.8 0.21
243 13.8 0.21
244 0.13
245 0.13
246
247 27.6
248
249
250
251
252 24
253 26
254 28
255 27
256 27.6
257 24.1
258 20.7 2.0E-07 0.18
259
260
261
262 27.6
263
264
265 27.6
266
267 20.7 2.0E-07 0.21
268
269 34.5 1.0E-05 PIN-ON-RING 19.6 1.9 6.7E+04 PIN
270 4.0E-08 BLOCK-ON-RING 124 24 2.4 4.3E+03 BLOCK
271 7.0E-09 BLOCK-ON-RING 134 0.15 220 BLOCK
272 8.0E-09 BLOCK-ON-RING 137 0.15 220 BLOCK
273 2.0E-09 BLOCK-ON-RING 402 0.15 220 BLOCK
274
275 3.0E-08 BLOCK-ON-RING 130 24 2.4 4310 BLOCK
276 3.0E-08 BLOCK-ON-RING 124 24 2.4 4360 BLOCK
277
278
279
280
281 10.3
282 33
283 26
284 10.3
285 248 1.0E-08 BLOCK-ON-RING 401 0.15 220 BLOCK
286 124 1.0E-08 BLOCK-ON-RING 137 0.15 220 BLOCK
287 124 2.0E-09 BLOCK-ON-RING 137 0.15 220 BLOCK
288
289
290
291
292
293 1.0E-04 PIN-ON-RING 19.6 1.9 6.7E+04 PIN
294 1
295
296
297 0.12 6.89 1.0E-09 0.21 2 BUSHING-SHAFT 24 0.5 BUSHING
298 7.0E-08 0.35 BUSHING-SHAFT 24 0.5 BUSHING
299 1.052
300 0.05
301
302 1.23 827
303 41
304 0.702 21 0.15
305 0.09 6.89 4.0E-09 0.28 3 BUSHING-SHAFT 24 0.5 BUSHING
306 34
307 0.0175 6.89 5.0E-08 0.38 5.1 BUSHING-SHAFT 24 0.5 BUSHING
308 4.0E-09 0.25 BUSHING-SHAFT 24 0.5 BUSHING
309 3.0E-10 1.5 BUSHING-SHAFT 24 0.5 BUSHING
310 2.0E-09 0.37 8.1 BUSHING-SHAFT 24 0.5 BUSHING
TABLE 15.1 Tribomaterials Database (Part F)
Contact EnvironmentStandard
TestCounterface
MaterialCounterface Description
Wear Type
AIR MILD STEEL ADHESIVE
Boundary lubricated, oil-filled material CARBON STEEL LUBRICATED
Boundary lubricated, oil-filled material CARBON STEEL LUBRICATED
AIR MILD STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL
AIR STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
CARBON STEEL ADHESIVE
CARBON STEEL ADHESIVE
AIR CARBON STEEL
AIR CARBON STEEL
AIR CARBON STEEL
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL
CARBON STEEL ADHESIVE
AIR CARBON STEEL
AIR CARBON STEEL ADHESIVE
AIR SILVER ADHESIVE
AFS 50/70 sand; 471 g/min CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
AIR 4620 CARBURIZED STEEL ADHESIVE
AIR 4620 CARBURIZED STEEL ADHESIVE
AIR 4620 CARBURIZED STEEL ADHESIVE
AFS 50/70 sand; 239 g/min ASTM G65-A CHLOROBUTYL A60 SHORE HARDNESS ABRASIVE
AFS 50/70 sand; 197 g/min CHLOROBUTYL A62 SHORE HARDNESS ABRASIVE
AIR CARBON STEEL
AIR 4620 CARBURIZED STEEL ADHESIVE
AIR 4620 CARBURIZED STEEL ADHESIVE
AIR 4620 CARBURIZED STEEL ADHESIVE
AIR ZINC ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
CARBON STEEL ADHESIVE
CARBON STEEL ADHESIVE
CARBON STEEL ADHESIVE
CARBON STEEL ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
TABLE 15.1 Tribomaterials Database (Part E)
NumberP*V Limit (MPa*m/s)
Maximum Pressure (MPa)
Wear Constant (mm3/mm*N)
Friction Coefficent
Maximum Velocity (m/s)
Contact Geometry
Load (N)
Temp. (C)
Velocity (m/s)
Distance (m)
Specimen Shape
311 0.07
312 0.017 6.0E-08 0.39 BUSHING-SHAFT 24 0.5 BUSHING
313 0.11 1.0E-08 0.24 BUSHING-SHAFT 24 0.5 BUSHING
314 BUSHING-SHAFT 24 0.5 BUSHING
315 0.18 3.0E-08 0.37 BUSHING-SHAFT 24 0.5 BUSHING
316 0.053 7.0E-09 0.37 BUSHING-SHAFT 24 0.5 BUSHING
317 0.049 3.45 4.0E-07 0.1 0.25 BUSHING-SHAFT 24 0.5 BUSHING
318 0.15
319 7
320 0.3
321 0.7 8.0E-10 0.14 BUSHING-SHAFT 24 0.5 BUSHING
322 5.0E-09 0.34 BUSHING-SHAFT 24 0.5 BUSHING
323 0.44 4.0E-10 0.16 4.1 BUSHING-SHAFT 24 0.5 BUSHING
324 0.32 5.0E-10 0.12 BUSHING-SHAFT 24 0.5 BUSHING
325 0.14 6.0E-09 0.16 BUSHING-SHAFT 24 0.5 BUSHING
326
327 0.88 13.8 8.0E-10 0.2 BUSHING-SHAFT 24 0.5 BUSHING
328 0.35 13.8 8.0E-10 0.31 BUSHING-SHAFT 24 0.5 BUSHING
329 0.61 2.0E-10 0.18 BUSHING-SHAFT 24 0.5 BUSHING
330 0.21 8.0E-10 0.09 BUSHING-SHAFT 24 0.5 BUSHING
331 50 0.2
332 0.53 41.4
333 1.58 0.26
334 0.3 2.0E-09 0.17 BUSHING-SHAFT 24 0.5 BUSHING
335 3.0E-09 0.22 BUSHING-SHAFT 24 0.5 BUSHING
336 0.7 2.0E-09 0.15 BUSHING-SHAFT 24 0.5 BUSHING
337 0.77 5.0E-10 0.15 BUSHING-SHAFT 24 0.5 BUSHING
338 2.0E-09 0.27 BUSHING-SHAFT 24 0.5 BUSHING
339 0.54 3.0E-10 0.17 BUSHING-SHAFT 24 0.5 BUSHING
340 1.0E-09 0.16 BUSHING-SHAFT 24 0.5 BUSHING
341 9.0E-10 0.13 BUSHING-SHAFT 24 0.5 BUSHING
342 BUSHING-SHAFT 24 0.5 BUSHING
343 6.0E-10 8.1 BUSHING-SHAFT 24 0.5 BUSHING
344 5.0E-09 0.27 BUSHING-SHAFT 24 0.5 BUSHING
345 2.0E-09 0.16 BUSHING-SHAFT 24 0.5 BUSHING
346 0.7 3.0E-09 0.2 BUSHING-SHAFT 24 0.5 BUSHING
347 0.56 5.0E-09 0.29 BUSHING-SHAFT 24 0.5 BUSHING
348 1.0E-09 0.1 BUSHING-SHAFT 24 0.5 BUSHING
349 0.18 7.0E-10 0.11 BUSHING-SHAFT 24 0.5 BUSHING
350 0.3 2.0E-09 0.14 BUSHING-SHAFT 24 0.5 BUSHING
351 3.0E-09 0.22 BUSHING-SHAFT 24 0.5 BUSHING
352 9.0E-10 0.14 BUSHING-SHAFT 24 0.5 BUSHING
353 3.0E-09 0.34 BUSHING-SHAFT 24 0.5 BUSHING
354 1.0E-09 0.32 BUSHING-SHAFT 24 0.5 BUSHING
355 1.23 138 4.0E-11 1 BUSHING-SHAFT 24 0.5 BUSHING
356 0.53 17.2 1.0E-10 0.09 5.1 BUSHING-SHAFT 24 0.5 BUSHING
357 0.56 17.2 6.0E-11 0.07 5.1 BUSHING-SHAFT 24 0.5 BUSHING
358 0.351 7
359 41
360 0.0105 55 0.3
361 0.0119 55 0.24
362
363
364
365
366
367
368 0.877 414 0.03
Notes:1. This Table is a row/column array of size 368 rows by 43 columns. Each row is a database record (the results of one or more tests); each column is a database
field (a significant test or material parameter). In printed form, it is necessary to subdivide the array to suit the printed page size. This was accomplishedby division of the array into 6 parts (A, B, C,…F) each containing 6 or more columns, and further dividing each part into 5 pages, resulting in 30 page-sized sub-arrays. The first sub-array is set of columns and rows starting at the upper left corner of the array. The next sub-array fits below the first, etc.Each page contains appropriate headings and seventy to eighty records that are numbered in the left-most column so that they can be followed across thearray. Every tenth record is followed by a solid line to facilitate reading.
2. The data records are sorted alphabetically by class, sub-class, and common name in that order. The common name field is shown first.3. Each record contains material description data and many but not all records have tribological test data.4. All records that contain tribological data result from sliding test conditions. All records refer to air environment testing unless special evironmental
conditions were established at the tribological contact and are so stated.5. The user is cautioned about use of any record where important test parameters are not given. This results from lack of reporting by the original source of
data. The significance of an incomplete description of test conditions or material description, and any resulting effect on the reported data, must be judgedby the individual user.
Data Sources:Alloy Digest, (Alloy Digest, Inc, Orange, N.J.).Ashby, M. F. and Jones, D. R. H., Engineering Materials, Pergammon, Oxford, (1980).ASM, International, Metals Handbooks, 8th edition (ASM Intern., Metals Park, OH 44073).ASM, International, Aluminum-Properties, Physical Metallurgy, Phase Diagrams, Vol.1(1967).
TABLE 15.1 Tribomaterials Database (Part F)
Contact EnvironmentStandard
TestCounterface
MaterialCounterface Description
Wear Type
CARBON STEEL ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
CARBON STEEL ADHESIVE
CARBON STEEL ADHESIVE
AIR CARBON STEEL
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
AIR CARBON STEEL COLD-ROLLED, 20 HRC, 16uin ADHESIVE
CARBON STEEL ADHESIVE
CARBON STEEL ADHESIVE
CARBON STEEL ADHESIVE
ASME, Wear of Materials, Conference Proceedings, (ASME, NY, 1977-1987).ASTM, unpublished data in ASTM Research Report relative to Standard G-65, (ASTM, W. Conshohocken, PA)ASME, Metals Properties, ASME Handbook (1954).Battelle Tribology Laboratory, Columbus, Ohio., private communication of unpublished data.Booser, E. R., ed. Handbook of Lubrication, Vol. I (1983) and Vol. II (1984) (CRC Press, Boca Raton, FL 33431).CRC Publ. Co., Handbook of Chemistry and Physics, 69th Edition, (1988).Encyclopedia of Chemical Technology, 3rd Edition, Vols. 3,4,16,18,23.Glaeser, W., pp. 313-326, in Wear Control Handbook, Peterson, M. B. and Winer, W. O., eds., ASME, New York, NY, 1980.Hertzberg, R. W., Deformation and Fracture Mechanics of Engineering Materials, 3rd ed., Wiley, NY, (1989).Lynch, C. T., Engineering Properties of Ceramics, AFML Report TR-66-52, WPAFB, (1966).Modern Plastics Encyclopedia-88 (McGraw Hill, NY, 1988).Morey, C. Properties of Glass, (1938).National Center of Tribology, Polymer Materials for Bearing Surfaces, (Risley, UK, 1983).NIST-Thermo-Physical Data Center, Thermophysical Properties of Matter; Data Series, Vols, 1,4 (1970).Rowe, C. N., pp. 143-160 in Wear Control Handbook, Peterson, M. B. and Winer, W. O., eds., ASME, New York, NY, 1980.Shah, Vishu, ed. Handbook of Plastics Testing Technology, (Wiley, 1984).Smithells Metal Reference Book, (Butterworths, London, 1955).Smithsonian Physical Tables, 9th Edition, (1964).Standards Handbook: Copper — Brass — Bronze, Alloy Data/7 and Alloy Data/2 (Copper Development Association Inc, 1985).Touloukin, Y. S. et al., Thermophysical Properties of Matter, (IFI Plenum, NY, 1972).