1,12-dodecanedioic acid

1,1-di-fluoro-ethene

1,3-dioxolane

1,4-diaminobutane

1,6-hexamethylene diamine

2,2-bis(4-hydroxyphenyl) propane

4-(4-hydroxyphenyl)phenol (BP)

4,4’-bisphenol A dianhydride (BPADA)

4,4’-diaminodiphenyl ether (ODA)

4,4’-diphenyl methane diisocyanate (MDI)

4-hydroxybenzoic acid (HBA)

4-methylpentene-1

6-hydroxynapthalene-2-carboxylic acid (HNA)

Abrasive wear

Acetal copolymer

Acetal polymers

Acetic acid

Acetic anhydride

Acid dianhydride

Acrylonitrile butadiene styrene (ABS)

Acrylonitrile styrene acrylate (ASA)

Acrylonitrile

Addition polymerization

Additives

Adhesive wear

Adipic acid

AISI 1080 carbon steel

Alternating copolymer

Amilan® CM3011N, coefficient of friction vs. load

Amilan™ CM1011G-15, flexural stress amplitude vs. cycles to failure

Amilan™ CM1011G-30, flexural stress amplitude vs. cycles to failure

Amilan™ CM1011G-45, flexural stress amplitude vs. cycles to failure

Amilan™ CM1011G-45, flexural stress amplitude vs. cycles to failure, 23°C, DAM

Amilan™ CM1011G-45, flexural stress amplitude vs. cycles to failure, 130°C, DAM

Amilan™ CM1011G-45, flexural stress amplitude vs. cycles to failure, 23°C, conditioned

Amilan™ CM1021, coefficient of friction vs. load, lubricated with water

Amilan™ CM1021, coefficient of friction vs. load, lubricated with molybdenum disulfide

Amilan™ CM1021, coefficient of friction vs. load, lubricated with machine oil

Aminolauric acid

Aminoundecanoic acid

Amodel® A-1133 HS, flexural stress amplitude vs. cycles to failure, 23°C

Amodel® A-1145 HS, flexural stress amplitude vs. cycles to failure, 100°C

Amodel® A-1145 HS, flexural stress amplitude vs. cycles to failure, 170°C

Amodel® A-1145 HS, flexural stress amplitude vs. cycles to failure, 23°C

Amorphous nylon

Amorphous

ANSI (American National Standards Institute)

Antiblocking agents

Antistatic agents

Aramid fiber

Arlon® 1260, dynamic coefficient of friction vs. temperature

Arlon® 1260, wear factor of friction vs. temperature

Arnite®, 35% glass fiber, stress amplitude vs. cycles to failure

Arnite®, unreinforced, stress amplitude vs. cycles to failure

Aromatic polyamide fiber

Asperities

ASTM 1248

ASTM D1044

ASTM D1894

ASTM D2176

ASTM D3702

ASTM D671

ASTM D671

ASTM D968

ASTM E606

ASTM G133

ASTM G75-07

ASTM G99

ASTM International

Average linear strain

Axial stress

Beach marks

Bending stress

Benzene-1,3-dicarboxylic acid (IA)

Benzene-1,4-dicarboxylic acid (TA)

Benzene-1,4-diol (HQ)

bis(p-aminocyclohexyl)methane

Bis-phenol A

bisphenol diamine

Block copolymer

Break-in period

Brineling

Brittle failure

Butadiene

Butadiene

Cantilevered beam flexural fatigue machine

Cantilevered beam

Caprolactam

Carbon fiber

Carbonic acid

Catalysts

Cavitation

Celanex®2000, Taber abrasion and COF

Celanex®2002, Taber abrasion and COF

Celanex®2012, Taber abrasion and COF

Celanex®2300 GV/30, flexural stress amplitude vs. cycles to failure

Celanex®2500, dynamic coefficient of friction vs. pressure loading

Celanex®2500, dynamic coefficient of friction vs. sliding speed

Celanex®3200, Taber abrasion and COF

Celanex®3210, flexural stress amplitude vs. cycles to failure

Celanex®3211, Taber abrasion and COF

Celanex®3300, flexural stress amplitude vs. cycles to failure

Celanex®3300, Taber abrasion and COF

Celanex®3310, flexural stress amplitude vs. cycles to failure

Celanex®3310, Taber abrasion and COF

Celanex®3311, Taber abrasion and COF

Celanex®3400, Taber abrasion and COF

Celanex®4300, Taber abrasion and COF

Celanex®5300, Taber abrasion and COF

Celanex®6400, Taber abrasion and COF

Celanex®7700, Taber abrasion and COF

Celcon®, glass reinforced, flexural stress amplitude vs. cycles to failure

Celcon®, unreinforced, flexural stress amplitude vs. cycles to failure

Celcon®, unspecified and unlubricated, limiting PV curve

Celcon®, unspecified, dynamic coefficient of friction vs. bearing pressure

Celcon®, unspecified, dynamic coefficient of friction vs. running speed

Celcon®, unspecified, radial wear vs. load at 12 m/min

Celcon®, unspecified, radial wear vs. load at 24 m/min

Celcon®, unspecified, radial wear vs. load at 3 m/min

Celcon®, unspecified, radial wear vs. load at 6 m/min

Celstran® PP-GF30, flexural stress amplitude vs. cycles to failure

Celstran® PP-GF40, flexural stress amplitude vs. cycles to failure

Chain reaction

Chemical attack

Chlorotrifluoroethylene

Chlorotrifluoroethylene

Clamshell marks

Classification of wear

Coefficient of friction

Coffin-Manson relation

Cold flow

Combustion modifiers

Composites

Compressive force

Compressive stress

Condensation polymerization

Copolymers

Coupling agents

Crack growth or propagation

Crack initiation or nucleation

Crastin®LW9020, flexural stress amplitude vs. cycles to failure

Crastin®LW9030, flexural stress amplitude vs. cycles to failure

Crastin®LW9130, flexural stress amplitude vs. cycles to failure

Crastin®SK00F10, flexural stress amplitude vs. cycles to failure

Crastin®SK00F10, flexural stress amplitude vs. cycles to failure

Crastin®SK602, flexural stress amplitude vs. cycles to failure

Crastin®SK603, flexural stress amplitude vs. cycles to failure

Crastin®SK605, flexural stress amplitude vs. cycles to failure

Crastin®SK609, flexural stress amplitude vs. cycles to failure

Crastin®SK645FR, flexural stress amplitude vs. cycles to failure

Cross-linked PE (PEX)

Cross-linked polymer

Crystalline

Cyclic Hardening exponent

Cyclic olefin copolymer

Cyclic strain amplitude

Cyclic strength coefficient

Cyclic stress amplitude

Cycolac® BDT5510, tensile stress amplitude vs. cycles to failure

Cycolac® BDT6500, tensile stress amplitude vs. cycles to failure

Cycolac® CGA, tensile stress amplitude vs. cycles to failure

Cycolac® CGF20, tensile stress amplitude vs. cycles to failure

Cycolac® CTR52, tensile stress amplitude vs. cycles to failure

Cycolac® EX38, tensile stress amplitude vs. cycles to failure

Cycolac® EX39, tensile stress amplitude vs. cycles to failure

Cycolac® EX75, tensile stress amplitude vs. cycles to failure

Cycolac® FR15, tensile stress amplitude vs. cycles to failure

Cycolac® FR23, tensile stress amplitude vs. cycles to failure

Cycolac® G-100, tensile stress amplitude vs. cycles to failure

Cycolac® KJB, tensile stress amplitude vs. cycles to failure

Cycolac® LDA, tensile stress amplitude vs. cycles to failure

Cycolac® MG38F, tensile stress amplitude vs. cycles to failure

Cycolac® MG47, tensile stress amplitude vs. cycles to failure

Cycolac® MGABS01, tensile stress amplitude vs. cycles to failure

Cycolac® MGX53GP, tensile stress amplitude vs. cycles to failure

Cycolac® X11, tensile stress amplitude vs. cycles to failure

Cycolac® X37, tensile stress amplitude vs. cycles to failure, 25Hz

Cycolac® X37, tensile stress amplitude vs. cycles to failure, 5Hz

Cycoloy® C1000, Taber Abrasion

Cycoloy® C1000, tensile stress amplitude vs. cycles to failure

Cycoloy® C1000HF, Taber Abrasion

Cycoloy® C1200, Taber Abrasion

Cycoloy® C1200HF, Taber Abrasion

Cycoloy® C1204HF, Taber Abrasion

Cycoloy® C2100, Taber Abrasion

Cycoloy® C2100HF, Taber Abrasion

Cycoloy® C2800, Taber Abrasion

Cycoloy® C2950, Taber Abrasion

Cycoloy® C3100, Taber Abrasion

Cycoloy® C3600, Taber Abrasion

Cycoloy® C3650, Taber Abrasion

Cycoloy® C6200, Taber Abrasion

Cycoloy® CU6800, Taber Abrasion

Cycoloy® CX5430, Taber Abrasion

Cycoloy® FXC630xy, Taber Abrasion

Cycoloy® FXC810xy, Taber Abrasion

Cycoloy® LG9000, Taber Abrasion

Damage tolerant design

Degree of crystallinity

Delrin® 100, coefficient of friction

Delrin® 100, flexural stress amplitude vs. cycles to failure

Delrin® 100, wear against various materials

Delrin® 100P, wear rate and dynamic COF

Delrin® 500, coefficient of friction

Delrin® 500, flexural stress amplitude vs. cycles to failure

Delrin® 500, stress amplitude vs. cycles to failure, 100°C

Delrin® 500, stress amplitude vs. cycles to failure, 23°C

Delrin® 500, stress amplitude vs. cycles to failure, 66°C

Delrin® 500, wear against mild steel in a thrust washer test

Delrin® 500, wear against various materials

Delrin® 500AF, wear rate and dynamic COF

Delrin® 500CL, coefficient of friction

Delrin® 500CL, wear against mild steel in a thrust washer test

Delrin® 500CL, wear rate and dynamic COF

Delrin® 500P, wear rate and dynamic COF

Delrin® 520MP, wear rate and dynamic COF

Delrin® 900, coefficient of friction

Delrin® 900, flexural stress amplitude vs. cycles to failure

Delrin® 900, wear against various materials

Delrin® 900P, wear rate and dynamic COF

Delrin® 900SP, wear rate and dynamic COF

Delrin® AF, coefficient of friction

Delrin®, the effect of Teflon ® PTFE levels on wear rate and dynamic coefficient of friction

Design against fatigue

Diakon™ CMG302, flexural stress amplitude vs. cycles to failure

Diamino diphenyl sulfone (DDS)

DIN (Deutsches Institut für Normung.-German Institute for Standardization)

Dioxolane

Dodecanoic acid

Ductile failure

Dyes

Dynamic coefficient of friction

Eccentric machines

Elastic limit

Elastic modulus

Elastic region

Elastomeric Alloy- Thermoplastic Vulcanizate

Elastomers

Electrohydraulic

Enduran®7062X, tensile stress amplitude vs. cycles to failure

Enduran®7065, tensile stress amplitude vs. cycles to failure

Enduran®7085, tensile stress amplitude vs. cycles to failure

Engineering strain

Engineering stress–strain curve

Engineering stress

Environmental chamber

EPDM

Equivalent stress

Erosion

ETFE, generic with 25% carbon fiber, flexural stress amplitude vs. cycles to failure

ETFE, generic with 25% glass fiber, flexural stress amplitude vs. cycles to failure

Ethylene – propylene rubber (EPR)

Ethylene oxide

Ethylene propylene rubber

Ethylene

Ethylene

Expanded polystyrene (EPS)

Extem® XH1005, tensile stress amplitude vs. cycles to failure

Extem® XH1006, tensile stress amplitude vs. cycles to failure

Extenders

External release agents

Extruded polystyrene (XPS)

Falex Corporation

Falling Abrasive/Erosion Test

Fatigue coupons

Fatigue crack growth rate curve

Fatigue crack growth rate

Fatigue crack propagation rate

Fatigue ductility coefficient

Fatigue ductility exponent

Fatigue Dynamics, Inc

Fatigue life

Fatigue limit

Fatigue strength coefficient

Fatigue strength exponent

Fatigue strength

Fatigue testing method

Fatigue testing

Final fracture

Finite lifetime concept

Fire retardants

Flame retardants

Flexural eccentric fatigue machine

Flexural oscillating fatigue tests

Flexural stress

Flexural test rig

Fluid lubricants

Fluorinated Ethylene Propylene (FEP)

Fluoroguard ®

Fluoropolymers

Formaldehyde

Fortron® 1140L4, flexural stress amplitude vs. cycles to failure

Fortron® 1140L4, flexural stress amplitude vs. cycles to failure

Fortron® 1140L4, tensile stress amplitude vs. cycles to failure, 23°C

Fortron® 1140L4, tensile stress amplitude vs. cycles to failure, 90°C

Fortron® 4184L4, flexural stress amplitude vs. cycles to failure

Fortron® 4665B5, flexural stress amplitude vs. cycles to failure

Fortron® 6160B4, flexural stress amplitude vs. cycles to failure

Fortron® 6165A4, tensile stress amplitude vs. cycles to failure, 23°C

Fortron® 6165A4, tensile stress amplitude vs. cycles to failure, 90°C

Fretting wear

Fretting

Friction

Frictional force

Frictional heating

Fusabond®

Galling

Geloy® CR7010, tensile stress amplitude vs. cycles to failure

Geloy® CR7020, tensile stress amplitude vs. cycles to failure

Geloy® CR7510, tensile stress amplitude vs. cycles to failure

Geloy® CR7520, tensile stress amplitude vs. cycles to failure

Geloy® XP4020R, tensile stress amplitude vs. cycles to failure

Geloy® XP4020R, tensile stress amplitude vs. cycles to failure

Geloy® XP4034, tensile stress amplitude vs. cycles to failure

Generic high-density PE, Fatigue crack propagation vs. stress intensity factor, MW=45000

Generic high-density PE, Fatigue crack propagation vs. stress intensity factor, MW=70000

Generic high-density PE, Fatigue crack propagation vs. stress intensity factor, MW=200000

Geon™ Fiberloc™ 85891, flexural stress amplitude vs. cycles to failure

Geon™ Fiberloc™ 87321, flexural stress amplitude vs. cycles to failure

Geon™ Fiberloc™ 87371, flexural stress amplitude vs. cycles to failure

Glass fibers

Glass transition temperature

Gouging

Grafted copolymer

Graphite

Grilamid® LV-5H, flexural stress amplitude vs. cycles to failure

Grilamid® TR-55, flexural stress amplitude vs. cycles to failure

Grilamid® TR-90, flexural stress amplitude vs. cycles to failure

Grilon® PV-5H, flexural stress amplitude vs. cycles to failure

Grivory® GC-4H, flexural stress amplitude vs. cycles to failure, 23°C

Grivory® GV-5H, flexural stress amplitude vs. cycles to failure

Grivory® GV-5H, flexural stress amplitude vs. cycles to failure, 23°C

Grivory® HT2V-5H, flexural stress amplitude vs. cycles to failure, 23°C

Grivory® HTV-5H1, flexural stress amplitude vs. cycles to failure, 23°C

Grivory® HTV-5H1, flexural stress amplitude vs. cycles to failure, 80°C

Grivory® HTV-6H1, flexural stress amplitude vs. cycles to failure, 23°C

Grivory® HTV-6H1, flexural stress amplitude vs. cycles to failure, 80°C

Grivory® HTV-6H1, flexural stress amplitude vs. cycles to failure, 120°C

Grivory® HTV-6H1, flexural stress amplitude vs. cycles to failure, 150°C

Grivory® HTV-6H1, flexural stress amplitude vs. cycles to failure, 180°C

GUR®, dynamic coefficient of friction vs. pressure

GUR®, dynamic coefficient of friction vs. sliding speed

GUR®, permissible unlubricated bearing load vs. sliding speed

GUR®, PV load limit vs. sliding speed

Haigh diagram

Halar® 600, tribological properties

Halar® 902, tribological properties

Halar®

Halar®, standard polymers, tribological properties

Halar®, standard polymers, tribological properties

Heterophasic copolymers

Hexafluoropropylene–Tetrafluoroethylene–Ethylene copolymer (THE)

Hexafluoropropylene

High temperature polymers

High-cycle fatigue

High-density PE (HDPE)

High-impact polystyrene, (HIPS)

HIPS, stress amplitude vs. cycles to failure

HIPS, stress amplitude vs. cycles to failure

HIPS, temperature rise vs. the number of fatigue cycles, stress amplitude 18.6

HIPS, temperature rise vs. the number of fatigue cycles, stress amplitude 17.2

HIPS, temperature rise vs. the number of fatigue cycles, stress amplitude 13.8

HIPS, temperature rise vs. the number of fatigue cycles, stress amplitude 12.4

HIPS, temperature rise vs. the number of fatigue cycles, stress amplitude 10.3

Homophasic copolymers

Hoop stress

Hostacom® G3 N01, flexural stress amplitude vs. cycles to failure

Hostacom® M2 N01, flexural stress amplitude vs. cycles to failure

Hostaform ® C 9021 +3% Si Oil, wear and dynamic coefficient of Friction

Hostaform ® C 9021 AW, wear and dynamic coefficient of Friction

Hostaform ® C 9021 G, wear and dynamic coefficient of Friction

Hostaform ® C 9021 GV1/30, flexural stress amplitude vs. cycles to failure, at 23°C and 10Hz

Hostaform ® C 9021 K, wear and dynamic coefficient of Friction

Hostaform ® C 9021 TF +3% Si Oil, wear and dynamic coefficient of Friction

Hostaform ® C 9021 TF, wear and dynamic coefficient of Friction

Hostaform ® C 9021, flexural stress amplitude vs. cycles to failure

Hostaform ® C 9021, flexural stress amplitude vs. cycles to failure, at 23°C and 10Hz

Hostaform ® C 9021, tensile stress amplitude vs. cycles to failure

Hostaform ® C 9021, torsional stress amplitude vs. cycles to failure, at 23°C and 10Hz

Hostaform ® C 9021, wear and dynamic coefficient of Friction

Hostaform ® C 9064, flexural stress amplitude vs. cycles to failure, at 23°C and 10Hz

Hostaform ® C 9244, flexural stress amplitude vs. cycles to failure, at 23°C and 10Hz

Hydrodynamic

Hydroquinone (HQ)

Hyflon® PFA M Series, MIT flex life vs. melt flow index

Hyflon® PFA P Series, MIT flex life vs. melt flow index

Hysteresis loop

Hysteretic heating

Imide polymer blends

Immiscible blends

Impact modifiers

Inclined plane

Infinite lifetime concept

Instron®

Internal lubrication

Internal release agents

ISO (International Organization for Standardization)

Isophthalic acid (IA)

IXEF® 1002, tribological properties

IXEF® 1022, flexural stress amplitude vs. cycles to failure, 23°C

IXEF® 1022, tribological properties

JIS (Japanese Industrial Standards)

Kevlar ®

Kinetic coefficient of friction

Kynar Flex® 2500, Taber abrasion

Kynar Flex® 2750-01, Taber abrasion

Kynar Flex® 2800-00, Taber abrasion

Kynar Flex® 2850-00, Taber abrasion

Kynar Flex® 2850-02, Taber abrasion

Kynar Flex® 2900-04, Taber abrasion

Kynar Flex® 2950-05, Taber abrasion

Kynar Flex® 3120-10, Taber abrasion

Kynar Flex® 3120-15, Taber abrasion

Kynar Flex® 3120-50, Taber abrasion

Kynar® 460, Taber abrasion

Kynar® 710, Taber abrasion

Lexan® 101, Taber abrasion performance

Lexan® 101, tensile stress amplitude vs. cycles to failure

Lexan® 101, tensile stress amplitude vs. cycles to failure

Lexan® 101R, coefficient of friction vs. temperature

Lexan® 121, Taber abrasion performance

Lexan® 141, Taber abrasion performance

Lexan® 141, tensile stress amplitude vs. cycles to failure

Lexan® 143R, Taber abrasion performance

Lexan® 143R, tensile stress amplitude vs. cycles to failure

Lexan® 191, Taber abrasion performance

Lexan® 191, tensile stress amplitude vs. cycles to failure

Lexan® 4501, tensile stress amplitude vs. cycles to failure

Lexan® 4701R, tensile stress amplitude vs. cycles to failure

Lexan® 500, Taber abrasion performance

Lexan® 500, tensile stress amplitude vs. cycles to failure

Lexan® 915R, tensile stress amplitude vs. cycles to failure

Lexan® 920, Taber abrasion performance

Lexan® 920, tensile stress amplitude vs. cycles to failure

Lexan® 925, tensile stress amplitude vs. cycles to failure

Lexan® 940, Taber abrasion performance

Lexan® 940, tensile stress amplitude vs. cycles to failure

Lexan® 945, tensile stress amplitude vs. cycles to failure

Lexan® 955, tensile stress amplitude vs. cycles to failure

Lexan® EM1210, tensile stress amplitude vs. cycles to failure

Lexan® EM2212, tensile stress amplitude vs. cycles to failure

Lexan® EM3110, tensile stress amplitude vs. cycles to failure

Lexan® HF1110, tensile stress amplitude vs. cycles to failure

Lexan® HF1130, tensile stress amplitude vs. cycles to failure

Lexan® HF1140, tensile stress amplitude vs. cycles to failure

Lexan® LS1, tensile stress amplitude vs. cycles to failure

Lexan® OQ1030, tensile stress amplitude vs. cycles to failure

Lifed part

Linear low-density PE (LLDPE)

Linear polymer

Linear Reciprocating Abrasion Testing

Liquid crystalline polymers (LCP)

Longitudinal stress

Low-cycle fatigue

Low-density PE (LDPE)

Lubricants

Lubrication

Lubricomp® BGU, flexural stress amplitude vs. cycles to failure, 23°C

Lubricomp® IFL-4036, flexural stress amplitude vs. cycles to failure

Lubricomp® QFL-4017 ER HS, flexural stress amplitude vs. cycles to failure

Lubriloy® FR-40, stress amplitude vs. cycles to failure

Lupolen® PE, dynamic coefficient of friction vs. pressure

Lupolen® PE, jet abrasion volume vs. jet velocity

Lupolen® PE, wear rate vs. mean pressure

Luran® 368 R, flexural stress amplitude vs. cycles to failure

Luran® S 757 R, flexural stress amplitude vs. cycles to failure

Luran® S 776 S, flexural stress amplitude vs. cycles to failure

Maleic anhydride

Mean strain

Mean stress offset

Mean stress

Medium-density PE (MDPE)

Methacrylic acid

Methyl methacrylate acrylonitrile butadiene styrene (MABS)

Methyl methacrylate

Methylene dianiline (MDA)

Mica

Migratory lubricant

Miller number

Minlon® 11C40, flexural stress amplitude vs. cycles to failure

Minlon® 12T, flexural stress amplitude vs. cycles to failure

Minlon® 20B, flexural stress amplitude vs. cycles to failure

MIT Flex life machine

MIT Flex life test

Modified polyphenylene ether/polyphenylene oxides

Modulus of elasticity

Modulus of rigidity

Molecular weight

Moly

Molybdenum disulfide

Molybdenum disulphide

Monomers

Monotonic stress-strain behavior

Monotonic stress-strain curves

m-phenylene diamine (MPD)

MTS Systems Corporation

Multibody impact wear

Multiphase polymer blends

m-xylylenediamine

Nanovea Corporation

Napthalene-2,6-dicarboxylic acid (NDA)

Necking

Network polymer

Neutral axis

Noncontact infrared thermometers

Nonisotropic materials

Norborene

Normal stress

Noryl®731, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®EM6100F, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®EM6101, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®EM7100, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®EM7304F, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®FN150X, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®FN215X, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®GFN1, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®GFN1, tensile stress amplitude vs. cycles to failure, 61°C

Noryl®GFN2, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®GFN3, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®GFN3, tensile stress amplitude vs. cycles to failure, 66°C

Noryl®GTX954, Tensile stress amplitude vs. cycles to failure, 23°C

Noryl®HH195, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®HS1000X, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®HS2000X, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®IGN320, tensile stress amplitude vs. cycles to failure, 100°C

Noryl®IGN320, tensile stress amplitude vs. cycles to failure, 150°C

Noryl®IGN320, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®PPX615, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®PPX630, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®PPX640, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®PPX7110, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®PPX7112, tensile stress amplitude vs. cycles to failure, 23°C

Noryl®PPX7115, tensile stress amplitude vs. cycles to failure, 23°C

Nylon

Nylon

Nylon

Nylon

Nylon 6, fatigue life vs. stress and heat treatment

Nylon 610

Nylon 612

Nylon 66

Nylon 66, generic, fatigue crack propagation rate vs. stress intensity factor, MW=17000

Nylon 66, generic, fatigue crack propagation rate vs. stress intensity factor, MW=34000

Nylon 66, generic, fatigue crack propagation rate vs. stress intensity factor,Hz=100

Nylon 66, generic, fatigue crack propagation rate vs. stress intensity factor,Hz=10

Nylon 66, generic, fatigue crack propagation rate vs. stress intensity factor,Hz=1

Nylon 666 or 66/6

Oxydianiline (ODA)

Paris’ Law

PEBAX®

PEEK, generic with SiC fiber, graphite and PTFE, tribological properties, medium molecular weight

PEEK, generic with SiC fiber, graphite and PTFE, tribological properties, high molecular weight

PEEK, generic, tribological properties, high molecular weight

PEEK, generic, tribological properties, low molecular weight

PEEK, generic, tribological properties, medium molecular weight

Perfluoro alkoxy (PFA)

Perfluoroethyl vinyl ether (EVE)

Perfluoromethyl vinyl ether (MVE)

Perfluoropolyether (PFPE) synthetic oil

Perfluoropropyl vinyl ether (PVE)

PES FO-10D, tribological properties

PES SGF2020R, tribological properties

PES SGF2030, tribological properties

PES SGF2040, tribological properties

Petra® 130, flexural stress amplitude vs. cycles to failure

Petra® 140, flexural stress amplitude vs. cycles to failure

PFPE

Phase -separated mixtures

Phthalates

Pigments

Pin-on-disk abrasion testing

Pin-on-disk tribometer

Pin-on-disk tribometer

Plastic region

Plastic strain amplitude

Plasticizers

Plexiglas®

Plint Tribology Products

Polishing wear

Poly-(4-methyl-1-pentene)

Poly(methyl methacrylate)

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. temperature, 1Hz

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. temperature, 100Hz

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. stress intensity factor, MW=110000

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. stress intensity factor, MW=190000

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. stress intensity factor, MW=350000

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. stress intensity factor, MW=230000

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. stress intensity factor, MW=360000

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. stress intensity factor, 0% crosslinking agent

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. stress intensity factor, 6.7% crosslinking agent

Poly(methyl methacrylate), generic, fatigue crack propagation rate vs. stress intensity factor, 11% crosslinking agent

Poly(methyl methacrylate), generic, tension/compression stress amplitude vs. cycles to failure, unnotched

Poly(methyl methacrylate), generic, tension/compression stress amplitude vs. cycles to failure, 1 mm notch

Poly(methyl methacrylate), generic, tension/compression stress amplitude vs. cycles to failure, 0.25 mm notch

Poly(methyl methacrylate), generic, tension/compression stress amplitude vs. cycles to failure, 0.01 mm notch

Polyacrylics

Polyamide -imide (PAI)

Polyamides

Polyarylamide (PAA.)

Polybenzimidazole (PBI)

Polybutadiene

Polybutylene terephthalate (PBT)

Polycarbonate (PC)

Polycarbonate, generic, fatigue crack propagation rate vs. temperature, 1Hz

Polycarbonate, generic, fatigue crack propagation rate vs. temperature, 100Hz

Polycarbonate, generic, fatigue crack propagation rate, 1Hz

Polycarbonate, generic, fatigue crack propagation rate, 10Hz

Polycarbonate, generic, fatigue crack propagation rate, 100Hz

Polychlorotrifluoroethylene (CTFE or PCTFE)

Polycyclohexylene -dimethylene terephthalate (PCT)

Polyester blends and alloys

Polyesters

Polyetheretherketones (PEEK)

Polyetherimide (PEI)

Polyethersulfone (PES)

Polyethylene chlorotrifluoroethylene (E-CTFE)

Polyethylene terephthalate (PET)

Polyethylene tetrafl uoroethylene (ETFE)

Polyethylene

Polyformaldehyde

Polyimide

Polymer blends

Polymer

Polymerization

Polymethyl pentene

Polyolefin TPE

Polyolefins

Polyoxymethylene (POM) homopolymer

Polyoxymethylene (POM) homopolymer, generic, various molecular weights, fatigue crack propagation vs. stress intensity factor

Polyoxymethylene copolymer (POM-Co)

Polyphenylene ether (PPE)

Polyphenylene oxide (PPO)

Polyphenylene sulfide (PPS)

Polyphenylsulfone (PPSU)

Polyphthalamide (PPA)/high-performance polyamide

Polyphthalate carbonate (PCC)

Polypropylene

Polysiloxane fluid

Polystyrene

Polystyrene, crosslinked, fatigue crack propagation

Polystyrene, fatigue crack propagation dependence on molecular weight

Polystyrene, fatigue crack propagation rates, frequency 0.1Hz

Polystyrene, fatigue crack propagation rates, frequency 1Hz

Polystyrene, fatigue crack propagation rates, frequency 10Hz

Polystyrene, fatigue crack propagation rates, frequency 100Hz

Polystyrene, fatigue life vs. stress and molecular weight

Polystyrene, stress amplitude vs. cycles to failure

Polysulfone (PSU)

Polysulfone (PSU), generic, fatigue crack propagation rate vs. temperature, 1Hz

Polysulfone (PSU), generic, fatigue crack propagation rate vs. temperature, 100Hz

Polytetrafluoroethylene (PTFE)

Polytetramethylene glycol segments (PTMG)

Polytrimethylene terephthalate (PTT)

Polyvinyl chloride

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, 100Hz

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, 10Hz

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, 1Hz

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, MW=61000

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, MW=67000

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, MW=97000

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, MW=95000

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, MW=106000

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, MW=141000

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, MW=225000

Polyvinyl chloride, generic, fatigue crack propagation rate vs. stress intensity factor, MW=205000

Polyvinylidene fluoride, (PVDF)

p-phenylene diamine (PDA)

Propylene

PTFE

PTFE, additive

PTFE, fatigue life vs. stress and crystallinity

PTFE, fatigue life

PTFE, generic with 25% carbon, dynamic coefficient of friction vs. temperature

PTFE, generic with 25% carbon, wear factor vs. temperature

PTFE, generic, flexural stress amplitude vs. cycles to failure, 10.7 mm thick

PTFE, generic, flexural stress amplitude vs. cycles to failure, 20Hz

PTFE, generic, flexural stress amplitude vs. cycles to failure, 3.6 mm thick

PTFE, generic, flexural stress amplitude vs. cycles to failure, 40Hz

PTFE, generic, flexural stress amplitude vs. cycles to failure, 60Hz

PTFE, generic, flexural stress amplitude vs. cycles to failure, 6.6 mm thick

PTFE, generic, flexural stress amplitude vs. cycles to failure, 320Hz

PTFE, generic, temperature rise vs. fatigue cycles, 10.3 MPa

PTFE, generic, temperature rise vs. fatigue cycles, 6.3 MPa

PTFE, generic, temperature rise vs. fatigue cycles, 6.9 MPa

PTFE, generic, temperature rise vs. fatigue cycles, 7.6 MPa

PTFE, generic, temperature rise vs. fatigue cycles, 8.3 MPa

PTFE, generic, temperature rise vs. fatigue cycles, 9.0 MPa

PTFE, measured temperature at failure

PTFE, testing frequency

Pulsator

PV limit

PV multiplier

PV value

PVC, fatigue crack propagation rate and toughener

PVDF, generic, fatigue crack propagation vs. stress intensity factor

Pyromellitic dianhydride (PMDA)

Radel®A A-200, flexural stress amplitude vs. cycles to failure

Radel®A AG-210, flexural stress amplitude vs. cycles to failure

Radel®A AG-220, flexural stress amplitude vs. cycles to failure

Radel®A AG-230, flexural stress amplitude vs. cycles to failure

Radel®A, Taber abrasion loss vs. glass fiber content

Radial stress

Random copolymer

Reinforcing fillers

Release agents

Retirement-for-cause

Rigid polyvinyl chloride

Riteflex® TPE

RTP 200 AR 15 TFE 15, wear properties at various PV levels, against steel

RTP 200 SI 2, wear properties at various PV levels, against self

RTP 200 SI 2, wear properties at various PV levels, against steel

RTP 200 TF 10 SI 2, wear properties at various PV levels, against steel

RTP 200 TF 10, wear properties at various PV levels, against self

RTP 200 TF 10, wear properties at various PV levels, against steel

RTP 200 TF 18 SI 2, wear properties at various PV levels, against steel

RTP 200 TF 18 SI 2, wear properties at various PV levels, against self

RTP 200 TF 20, wear properties at various PV levels, against self

RTP 200 TF 20, wear properties at various PV levels, against steel

RTP 200 TF 5, wear properties at various PV levels, against steel

RTP 200D TFE 10, wear properties at various PV levels, against self

RTP 200D TFE 10, wear properties at various PV levels, against steel

RTP 200D TFE 18 SI 2, wear properties at various PV levels, against steel

RTP 200D TFE 18 SI 2, wear properties at various PV levels, against self

RTP 200D TFE 20, wear properties at various PV levels, against self

RTP 200D TFE 20, wear properties at various PV levels, against steel

RTP 202 TF 15 SI 2, wear properties at various PV levels, against steel

RTP 202 TF 15 SI 2, wear properties at various PV levels, against self

RTP 202 TF 15, wear properties at various PV levels, against self

RTP 202 TF 15, wear properties at various PV levels, against steel

RTP 202D TFE 15, wear properties at various PV levels, against self

RTP 202D TFE 15, wear properties at various PV levels, against steel

RTP 205 TF 15, wear properties at various PV levels, against steel

RTP 207A TFE 13 SI 2 HS, wear properties at various PV levels

RTP 207A TFE 20 HS, wear properties at various PV levels

RTP 2100 AR 15 TFE 15, wear properties at various PV levels

RTP 2200 AR 15 TFE 15, wear properties at various PV levels

RTP 2200 LF TFE 15, wear properties at various PV levels

RTP 2200 LF TFE 20, wear properties at various PV levels

RTP 2205 TFE 15, wear properties at various PV levels

RTP 2285 TFE 15, wear properties at various PV levels

RTP 2299 x 57352 A, wear properties at various PV levels

RTP 282 TF 13 SI 2, wear properties at various PV levels, against steel

RTP 282 TF 13 SI 2, wear properties at various PV levels, against self

RTP 282 TF 15, wear properties at various PV levels, against self

RTP 282 TF 15, wear properties at various PV levels, against steel

RTP 282D TFE 15, wear properties at various PV levels, against self

RTP 282D TFE 15, wear properties at various PV levels, against steel

RTP 285 TF 13 SI 2, wear properties at various PV levels, against steel

RTP 285D TFE 15, wear properties at various PV levels, against self

RTP 285D TFE 15, wear properties at various PV levels, against steel

RTP 299A x 82678 C, wear properties at various PV levels

RTP 299A x 90821, wear properties at various PV levels

RTP 299B x 89491 A, wear properties at various PV levels

RTP 300 AR 10 TFE 10, wear properties against steel at various PV levels

RTP 300 AR 10, wear properties against steel at various PV levels

RTP 300 TFE 10 SI 2, wear properties against steel at various PV levels

RTP 300 TFE 10, wear properties against steel at various PV levels

RTP 300 TFE 10, wear properties at various PV levels against self

RTP 300 TFE 15, wear properties against steel at various PV levels

RTP 300 TFE 15, wear properties at various PV levels against self

RTP 300 TFE 20, wear properties against steel at various PV levels

RTP 300 TFE 20, wear properties at various PV levels against self

RTP 300 TFE 5, wear properties against steel at various PV levels

RTP 300 TFE 5, wear properties at various PV levels against self

RTP 302 TFE 15, wear properties against steel at various PV levels

RTP 305 TFE 15, wear properties against steel at various PV levels

RTP 382 TFE 15, wear properties against self at various PV levels

RTP 382 TFE 15, wear properties against steel at various PV levels

RTP 385 TFE 15, wear properties against steel at various PV levels

RTP 4205 TFE 15, wear properties at various PV levels

RTP 4285 TFE 15, wear properties at various PV levels

RTP 4299 x 64425, wear properties at various PV levels

RTP 4299 x 71927, wear properties at various PV levels

RTP 800 SI 2, wear properties at various PV levels

RTP 800 TFE 10 SI2, wear properties at various PV levels

RTP 800 TFE 10, wear properties at various PV levels

RTP 800 TFE 20 DEL, wear properties at various PV levels

RTP 800 TFE 5, wear properties at various PV levels

RTP 800, wear properties at various PV levels

RTP ESD 800, wear properties at various PV levels

Rynite® 408, flexural stress amplitude vs. cycles to failure

Rynite® 415HP, flexural stress amplitude vs. cycles to failure

Rynite® 530, flexural stress amplitude vs. cycles to failure

Rynite® 535, flexural stress amplitude vs. cycles to failure

Rynite® 545, flexural stress amplitude vs. cycles to failure

Rynite® 555, flexural stress amplitude vs. cycles to failure

Rynite® 940, flexural stress amplitude vs. cycles to failure

Rynite® FR515, flexural stress amplitude vs. cycles to failure

Rynite® FR530L, flexural stress amplitude vs. cycles to failure

Rynite® FR543, flexural stress amplitude vs. cycles to failure

Rynite® FR943, flexural stress amplitude vs. cycles to failure

Rynite® SST35, flexural stress amplitude vs. cycles to failure

Rynite®415HP, Taber abrasion and COF

Rynite®530, Taber abrasion and COF

Rynite®530, Taber abrasion and COF

Rynite®545, Taber abrasion and COF

Rynite®555, Taber abrasion and COF

Rynite®935, flexural stress amplitude vs. cycles to failure

Rynite®935, Taber abrasion and COF

Rynite®940, Taber abrasion and COF

Rynite®FR330, Taber abrasion and COF

Rynite®FR515, Taber abrasion and COF

Rynite®FR530, Taber abrasion and COF

Rynite®FR543, Taber abrasion and COF

Rynite®FR943, Taber abrasion and COF

Rynite®FR945, Taber abrasion and COF

Rynite®FR946, Taber abrasion and COF

Rynite®SST35, Taber abrasion and COF

Ryton® A-200, Taber abrasion

Ryton® A-200, tensile stress retained vs. cycles to failure

Ryton® R-4 02XT, tensile stress retained vs. cycles to failure

Ryton® R-4, coefficient of friction

Ryton® R-4, Taber abrasion

Ryton® R-7, Taber abrasion

Ryton® R-7, tensile stress retained vs. cycles to failure

S –N curve

SAE (Society of Automotive Engineers)

Safe-life design practice

Sebacic acid

Semicrystalline polyamide (PACM 12)

Servo hydraulic

Shear stress

Silicone resin

Silicone

Slip agents

Slurry Abrasion Response (SAR Number)

Slurry abrasivity

Slurry erosion

Smoke suppressants

S-N curve

Solef® 1010, tensile stress amplitude vs. cycles to failure, 100°C

Solef® 1010, tensile stress amplitude vs. cycles to failure, 20°C

Solef® 1010, tensile stress amplitude vs. cycles to failure, 60°C

Solef® PVDF, tensile stress amplitude vs. cycles to failure

Solvay Solexis M620, flex life

Solvay Solexis M640, flex life

Solvay Solexis P420, flex life

Solvay Solexis P450, flex life

Spalling

Stanyl® TE200F6, flexural stress amplitude vs. cycles to failure

Static coefficient of friction

Stat-Kon®WC-4036, flexural stress amplitude vs. cycles to failure

Strain amplitudes

Strain life curve

Strain life plot

Strain range

Strain-life behavior

Stress intensity factor (K)

Stress intensity factor range

Stress intensity

Stress range

Stress/strain amplitude

Stress-life behavior

Striations

Stroke set

Styrene acrylonitrile (SAN)

Styrene maleic anhydride (SMA)

Styrene

Styrenic blends

Styrenic block copolymer (SBC)

Styrenic block copolymer TPEs

Styrenic plastics

Styrofoam™

Supec® G401, flexural stress amplitude vs. cycles to failure

Supec® G401, tensile stress amplitude vs. cycles to failure

Supec® G620, flexural stress amplitude vs. cycles to failure

Supported structural beam bending

Surfaces scratches

Taber abraser

Tangential shear stress

Teflon ® PTFE, coefficient of friction vs. sliding speed

Teflon® FEP, 10% bronze, tribological properties

Teflon® FEP, 15% glass fiber, tribological properties

Teflon® FEP, dynamic coefficient of friction vs. sliding speed, 0.007 MPa

Teflon® FEP, dynamic coefficient of friction vs. sliding speed, 0.07 MPa

Teflon® FEP, dynamic coefficient of friction vs. sliding speed, 0.69 MPa

Teflon® PTFE, 15% glass fiber, tribological properties

Teflon® PTFE, 15% graphite, tribological properties

Teflon® PTFE, 20% glass and 5% graphite, tribological properties

Teflon® PTFE, 20% glass and 5% MoS₂, tribological properties

Teflon® PTFE, 25% carbon, tribological properties

Teflon® PTFE, 25% glass fiber, tribological properties

Teflon® PTFE, 60% bronze, tribological properties

Teflon® PTFE, dynamic coefficient of friction vs. sliding speed, 0.3 MPa

Teflon® PTFE, dynamic coefficient of friction vs. sliding speed, 0.1 MPa

Teflon® PTFE, dynamic coefficient of friction vs. sliding speed, 0.5 MPa

Teflon® PTFE, neat, tribological properties

Teflon®

Tefzel® ETFE HT-200, flexural stress amplitude vs. cycles to failure

Tefzel® ETFE HT-2004, bearing wear vs. PV

Tefzel® ETFE HT-2004, coefficient of friction vs. PV

Tefzel® ETFE HT-2004, flexural stress amplitude vs. cycles to failure

Tefzel® ETFE HT-2004, static coefficient of friction

Tensile eccentric fatigue machine

Tensile force

Tensile stress

Terephthalic acid (TA)

Tetrafluoroethylene (TFE)

Thermal stabilizers

Thermocomp® BF-1006, Flexural stress amplitude vs. cycles to failure

Thermocomp® CF-1006, Flexural stress amplitude vs. cycles to failure

Thermocomp® CF-1008, Flexural stress amplitude vs. cycles to failure

Thermocomp® GF-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® GF-1008, flexural stress amplitude vs. cycles to failure

Thermocomp® IF-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® JC-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® JF-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® JF-1008, flexural stress amplitude vs. cycles to failure

Thermocomp® MF-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® PF-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® QF-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® QF-1008, flexural stress amplitude vs. cycles to failure

Thermocomp® RC-1002, flexural stress amplitude vs. cycles to failure

Thermocomp® RC-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® RC-1008, flexural stress amplitude vs. cycles to failure

Thermocomp® RF-1006, flexural stress amplitude vs. cycles to failure

Thermocomp® RF-1008, flexural stress amplitude vs. cycles to failure

Thermocomp® UC-1008, flexural stress amplitude vs. cycles to failure, 23°C

Thermocomp® UF-1006, flexural stress amplitude vs. cycles to failure, 23°C

Thermocomp®WC-1006, flexural stress amplitude vs. cycles to failure

Thermocomp®WF-1006, flexural stress amplitude vs. cycles to failure

Thermocomp®ZF-1006, tensile stress amplitude vs. cycles to failure, 23°C

Thermocouples

Thermoplastic copolyester elastomers

Thermoplastic elastomers

Thermoplastic polyether block amide elastomers

Thermoplastic polyimide

Thermoplastic polyurethane elastomers

Thermoplastics

Thermosets

Threshold regime

Thrust washer abrasion test

Thrust washer abrasion testing

THV™

Torelina® A504, coefficient of abrasion vs. PV value, against itself

Torelina® A504, coefficient of abrasion vs. PV value, against steel

Torelina® A504, stress amplitude vs. cycles to failure, 110°C

Torelina® A504, stress amplitude vs. cycles to failure, 160°C

Torelina® A504, stress amplitude vs. cycles to failure, 180°C

Torelina® A504X90, stress amplitude vs. cycles to failure, 110°C

Torelina® A504X90, stress amplitude vs. cycles to failure, 160°C

Torelina® A504X90, stress amplitude vs. cycles to failure, 180°C

Torlon® 4203L, flexural stress amplitude vs. cycles to failure, 30Hz

Torlon® 4203L, flexural stress amplitude vs. cycles to failure, 30Hz, 177°C

Torlon® 4203L, tensile stress amplitude vs. cycles to failure

Torlon® 4275, flexural stress amplitude vs. cycles to failure, 30Hz

Torlon® 4275, wear factor at various PV

Torlon® 4275, wear rate at various PV

Torlon® 4275, wear resistance vs. pressure, velocity=0.25m/sec

Torlon® 4275, wear resistance vs. pressure, velocity=1.02m/sec

Torlon® 4275, wear resistance vs. pressure, velocity=4.06m/sec

Torlon® 4301, extended cure, wear factor vs. pressure, velocity=1.02m/sec

Torlon® 4301, wear factor at various PV

Torlon® 4301, wear rate at various PV

Torlon® 4301, wear resistance vs. pressure, velocity=0.25m/sec

Torlon® 4301, wear resistance vs. pressure, velocity=1.02m/sec

Torlon® 4301, wear resistance vs. pressure, velocity=4.06m/sec

Torlon® 4435, wear factor at various PV

Torlon® 4435, wear rate at various PV

Torlon® 4435, wear resistance vs. pressure, velocity=0.25m/sec

Torlon® 4435, wear resistance vs. pressure, velocity=1.02m/sec

Torlon® 4435, wear resistance vs. pressure, velocity=4.06m/sec

Torlon® 5030, flexural stress amplitude vs. cycles to failure, 30Hz

Torlon® 5030, flexural stress amplitude vs. cycles to failure, 30Hz, 177°C

Torlon® 7130, flexural stress amplitude vs. cycles to failure, 30Hz

Torlon® 7130, flexural stress amplitude vs. cycles to failure, 30Hz, 177°C

Torlon® 7130, tensile stress amplitude vs. cycles to failure, 2Hz

Torlon® 7130, tensile stress amplitude vs. cycles to failure, 30Hz

Torsional constant (K)

Torsional stress

Total true strain

Tougheners

Transition life

Tribology additives

Tribology

Tribometers

Trifluoromethyl group

Trimellitic anhydride (TMA)

Trimethyl hexamethylene diamine

Trioxane

Trogamid® CX7323, abrasion resistance

Trogamid® T5000, fatigue crack propagation rate vs. stress intensity factor

Trogamid® T5000, flexural stress amplitude vs. cycles to failure

True fracture strain

True fracture strength

True strain

True stress

Two-body impact wear

Ultem® 1000, Taber abrasion

Ultem® 1000, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 1000, tensile stress amplitude vs. cycles to failure, 77°C

Ultem® 1010, Taber abrasion

Ultem® 1010, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 2100, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 2200, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 2212, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 2300, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 2300, tensile stress amplitude vs. cycles to failure, 77°C

Ultem® 2310, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 2312, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 2400, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 2400, tensile stress amplitude vs. cycles to failure, 77°C

Ultem® 3452, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 4000, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 4000, tribological properties

Ultem® 4001, tensile stress amplitude vs. cycles to failure, 23°C

Ultem® 4001, tribological properties

Ultem® 9075, tensile stress amplitude vs. cycles to failure

Ultem® 9076, tensile stress amplitude vs. cycles to failure

Ultem® AR9100, tensile stress amplitude vs. cycles to failure

Ultem® AR9200, tensile stress amplitude vs. cycles to failure

Ultem® AR9300, tensile stress amplitude vs. cycles to failure

Ultem® CRS5001, tensile stress amplitude vs. cycles to failure

Ultem® CRS5001,Taber abrasion

Ultem® CRS5011, tensile stress amplitude vs. cycles to failure

Ultem® CRS5311, tensile stress amplitude vs. cycles to failure

Ultem® D9065, tensile stress amplitude vs. cycles to failure

Ultem® LTX300B, tensile stress amplitude vs. cycles to failure

Ultem® XH6050, tensile stress amplitude vs. cycles to failure

Ultimate tensile strength

Ultraform ® N2200 G53, flexural stress amplitude vs. cycles to failure, at 23°C and 10Hz

Ultraform ® N2310P, coefficient of sliding friction vs. roughness

Ultraform ® N2310P, wear rate vs. roughness

Ultraform ® N2320 003, coefficient of sliding friction vs. roughness

Ultraform ® N2320 003, flexural stress amplitude vs. cycles to failure, at 23°C and 10Hz

Ultraform ® N2320 003, wear rate vs. roughness

Ultrahigh Molecular Weight PE (UHMWPE)

Ultrahigh Molecular Weight PE (UHMWPE), generic, fatigue crack propagation vs. stress intensity factor, unfilled

Ultrahigh Molecular Weight PE (UHMWPE), generic, fatigue crack propagation vs. stress intensity factor, carbon fiber filled

Ultralow-density PE (ULDPE)

Ultramid® A 3HG5, flexural stress amplitude vs. cycles to failure, 23°C

Ultramid® A 3HG5, flexural stress amplitude vs. cycles to failure, 90°C

Ultramid® A 3WG7, flexural stress amplitude vs. cycles to failure, 23°C

Ultramid® A 3WG7, flexural stress amplitude vs. cycles to failure, 90°C

Ultramid® AG5, stress amplitude vs. cycles to failure

Ultramid® AG7, stress amplitude vs. cycles to failure

Ultramid® B 3WG6, flexural stress amplitude vs. cycles to failure, 23°C, conditioned

Ultramid® B 3WG6, flexural stress amplitude vs. cycles to failure, 90°C

Ultramid® BG5, stress amplitude vs. cycles to failure

Ultramid® BG7, stress amplitude vs. cycles to failure

Ultrason® E 2010 G4, flexural stress amplitude vs. cycles to failure

Ultrason® E 2010 G4, tribological properties

Ultrason® E 2010 G6, tribological properties

Ultrason® E 2010, flexural stress amplitude vs. cycles to failure

Ultrason® E 2010, tribological properties

Ultrason® KR 4113, tribological properties

Ultrason® S 2010 G4, flexural stress amplitude vs. cycles to failure

Ultrason® S 2010 G4, tribological properties

Ultrason® S 2010 G6, tribological properties

Ultrason® S 2010, flexural stress amplitude vs. cycles to failure

Ultrason® S 2010, tribological properties

Underwriters Laboratories

UV stabilizers

Valox®310, tensile stress amplitude vs. cycles to failure

Valox®325, tensile stress amplitude vs. cycles to failure

Valox®337, tensile stress amplitude vs. cycles to failure

Valox®368, tensile stress amplitude vs. cycles to failure

Valox®3706, tensile stress amplitude vs. cycles to failure

Valox®412E, tensile stress amplitude vs. cycles to failure

Valox®420, tensile stress amplitude vs. cycles to failure

Valox®430, tensile stress amplitude vs. cycles to failure

Valox®508, tensile stress amplitude vs. cycles to failure, 23°C

Valox®508, tensile stress amplitude vs. cycles to failure, 82°C

Valox®732E, tensile stress amplitude vs. cycles to failure

Valox®736, tensile stress amplitude vs. cycles to failure

Valox®865, tensile stress amplitude vs. cycles to failure

Valox®AE7370, tensile stress amplitude vs. cycles to failure

Valox®CS860, tensile stress amplitude vs. cycles to failure

Valox®EF3500, tensile stress amplitude vs. cycles to failure

Valox®EF4517, tensile stress amplitude vs. cycles to failure

Valox®EF4530, tensile stress amplitude vs. cycles to failure

Valox®HV7075, tensile stress amplitude vs. cycles to failure

Valox®V4280, tensile stress amplitude vs. cycles to failure

Vectra® A115, coefficient of friction

Vectra® A130, coefficient of friction

Vectra® A130, dynamic coefficient of friction

Vectra® A130, flexural stress amplitude vs. cycles to failure

Vectra® A130, wear volume

Vectra® A150, coefficient of friction

Vectra® A230, coefficient of friction

Vectra® A230, dynamic coefficient of friction

Vectra® A230, wear volume

Vectra® A410, coefficient of friction

Vectra® A430, coefficient of friction

Vectra® A430, dynamic coefficient of friction

Vectra® A430, wear volume

Vectra® A435, coefficient of friction

Vectra® A435, dynamic coefficient of friction

Vectra® A435, wear volume

Vectra® A515, coefficient of friction

Vectra® A530, dynamic coefficient of friction

Vectra® A530, wear volume

Vectra® A625, coefficient of friction

Vectra® A625, dynamic coefficient of friction

Vectra® A625, wear volume

Vectra® B130, dynamic coefficient of friction

Vectra® B130, wear volume

Vectra® B230, dynamic coefficient of friction

Vectra® B230, flexural stress amplitude vs. cycles to failure

Vectra® B230, wear volume

Vectra® C130, dynamic coefficient of friction

Vectra® C130, wear volume

Vectra® L130, coefficient of friction

Vectra® L130, dynamic coefficient of friction

Vectra® L130, wear volume

Vectra®B230, coefficient of friction

Vertical applied force

Verton® MFX-700-10 HS, flexural stress amplitude vs. cycles to failure

Verton® MFX-7006 HS, flexural stress amplitude vs. cycles to failure

Verton® MFX-7008 HS, flexural stress amplitude vs. cycles to failure

Verton® RF-700-10 EM HS, flexural stress amplitude vs. cycles to failure

Verton® RF-700-12 EM HS, flexural stress amplitude vs. cycles to failure

Verton® RF-7007 EM HS, flexural stress amplitude vs. cycles to failure

Very low-density PE (VLDPE)

Vespel® CR-6100, dynamic coefficient of friction vs. temperature

Vespel® CR-6100, tribological properties

Vespel® CR-6100, wear factor vs. temperature

Vespel® SP1, fatigue resistance vs. temperature

Vespel® SP1, tribological properties

Vespel® SP-21, coefficient of friction vs. lubrication

Vespel® SP-21, coefficient of friction vs. temperature

Vespel® SP21, dynamic coefficient of friction vs. temperature

Vespel® SP21, dynamic coefficient of friction vs. time

Vespel® SP21, dynamic coefficient of friction vs. ZN/P

Vespel® SP21, fatigue resistance vs. temperature

Vespel® SP21, tribological properties

Vespel® SP21, wear factor vs. ZN/P

Vespel® SP-21, wear factor vs. hardness

Vespel® SP-21, wear factor vs. roughness

Vespel® SP21, wear factor vs. temperature limit at 395°C

Vespel® SP-21, wear factor vs. temperature

Vespel® SP21, wear rate vs. hardness

Vespel® SP21, wear rate vs. PV

Vespel® SP21, wear rate vs. roughness

Vespel® SP211, dynamic coefficient of friction vs. temperature

Vespel® SP211, pressure vs. velocity limit at 395°C

Vespel® SP211, tribological properties

Vespel® SP211, wear factor vs. temperature limit at 395°C

Vespel® SP22, tribological properties

Vespel® SP3, tribological properties

Vespel® TP-8054, tensile stress amplitude vs. cycles to failure

Vespel® TP-8130, tensile stress amplitude vs. cycles to failure

Vespel® TP-8130, tribological properties

Vespel® TP-8311, tribological properties

Vespel® TP-8395, tensile stress amplitude vs. cycles to failure

Vespel® TP-8549, tribological properties

Vestamid® L1600, Taber abrasion

Vestamid® L1670, Taber abrasion

Vestamid® L1901, abrasion vs. sliding distance

Vestamid® L1901, dynamic coefficient of friction vs. bearing pressure

Vestamid® L1901, dynamic coefficient of friction vs. bearing temperature

Vestamid® L1930, Taber abrasion

Vestamid® L1950, Taber abrasion

Vestamid® L2101F, Taber abrasion

Vestamid® L2124, Taber abrasion

Vestamid® L2128, Taber abrasion

Vestamid® L2140, Taber abrasion

Vestamid® L-GB30, abrasion vs. sliding distance

Vestamid® L-GB30, Taber abrasion

Vestamid® L-GF30, abrasion vs. sliding distance

Vestodur®2000, sliding coefficient of friction vs. pressure

Victrex® 450CA30, tribological properties

Victrex® 450FC30, dynamic coefficient of friction vs. temperature

Victrex® 450FC30, tribological properties

Victrex® 450G, tribological properties

Vinyl benzene

Vinyl chloride

Vinylidene fluoride

Von Mises equivalent stress formula

Water absorption

Wear factor

Wear rate

Wear transition temperature

Wear

Wöhler curve

Xenoy®1102, tensile stress amplitude vs. cycles to failure

Xenoy®1103, tensile stress amplitude vs. cycles to failure

Xenoy®1402B, tensile stress amplitude vs. cycles to failure

Xenoy®1403B, tensile stress amplitude vs. cycles to failure

Xenoy®1731, tensile stress amplitude vs. cycles to failure

Xenoy®1732, tensile stress amplitude vs. cycles to failure

Xenoy®1760E, tensile stress amplitude vs. cycles to failure

Xenoy®2230, tensile stress amplitude vs. cycles to failure

Xenoy®2390, tensile stress amplitude vs. cycles to failure

Xenoy®5220, tensile stress amplitude vs. cycles to failure

Xenoy®5230, tensile stress amplitude vs. cycles to failure

Xenoy®5770, tensile stress amplitude vs. cycles to failure, 23°C

Xenoy®5770, tensile stress amplitude vs. cycles to failure, 80°C

Xenoy®6172, tensile stress amplitude vs. cycles to failure

Xenoy®6240, tensile stress amplitude vs. cycles to failure

Xenoy®6370, tensile stress amplitude vs. cycles to failure

Xenoy®6620, tensile stress amplitude vs. cycles to failure

Xenoy®CL101, tensile stress amplitude vs. cycles to failure

Xenoy®K4630, tensile stress amplitude vs. cycles to failure

Xenoy®X2300WX, tensile stress amplitude vs. cycles to failure

Xenoy®X5300WX, tensile stress amplitude vs. cycles to failure

Yield point

Yield stress

Young’s modulus

Zenite® 6130 BK010, flexural stress amplitude vs. cycles to failure

Zytel® 101, axial stress amplitude vs. cycles to failure, 100°C

Zytel® 101, axial stress amplitude vs. cycles to failure

Zytel® 101, axial stress amplitude vs. cycles to failure, 23°C

Zytel® 101, axial stress amplitude vs. cycles to failure, 66°C

Zytel® 101, flexural stress amplitude vs. cycles to failure

Zytel® 101, flexural stress amplitude vs. cycles to failure, 23°C, conditioned

Zytel® 101, flexural stress amplitude vs. cycles to failure, 23°C, DAM

Zytel® 122L, fatigue crack propagation rate vs. stress intensity factor

Zytel® 158L NC010, axial stress amplitude vs. cycles to failure

Zytel® 408L, axial stress amplitude vs. cycles to failure

Zytel® 70G33L, flexural stress amplitude vs. cycles to failure