1、材料英语证书考试(PEC)-材料试验词汇A AdherenceThe extent to which a coating bonds to a substrate. Adherence Index-Measure of the Adherence of porcelain enamel and ceramic coatings to sheet metal. Alpha Rockwell HardnessIndex of the resistance of a plastic to surface penetration by a specified indenter under specif
2、ied load applied with a Rockwell Hardness tester. Higher values indicate higher indentation Hardness. Axial StrainThe Strain in the direction that the load is applied, or on the same axis as the applied load. Analogue boardA machine circuit board, which converts analogue signals into digital signal.
3、 Anchor PinA steel pin that connects a grip or jig to an eye end Auto ReturnAuto Return, when set to on, causes the crosshead to return automatically to its Zero point at the end of the test. B Bend TestMethod for measuring Ductility of certain materials. There are no standardized terms for reportin
4、g bend test results for broad classes of materials; rather, terms associated with bend tests apply to specific forms or types of materials. For example, materials specifications sometimes require that a specimen be bent to a specified inside diameter (ASTM A-360, steel products). A bend test for Duc
5、tility of welds is given in ASTM E-190. Results of tests of fiberboard are reported by a description of the failure or photographs. Bending StrengthAlternate term for Flexural Strength. It is most commonly used to describe flexure properties of cast iron and wood products. Bond StrengthStress (tensi
6、le load divided by area of bond) required to rupture a bond formed by an adhesive between two metal blocks. Break ElongationThe Elongation of the specimen to the break point. Breaking LoadLoad which causes fracture in a tensile, compression, flexure or Torsion Test. In tensile tests of textiles and
7、yarns, breaking load also is called breaking strength. In tensile tests of thin sheet materials or materials in form of small diameter wire it is difficult to distinguish between breaking load and the maximum load developed, so the latter is considered the breaking load. Breaking StrengthStress requ
8、ired rupturing the specimen. GLOSSARY OF MATERIALS TESTING Bulk Modulus of ElasticityRatio of Stress to change in volume of a material subjected to axial loading. Related to Modulus of Elasticity (E) and Poissons Ratio (r) by the following equation: Bulk Modulus K=E/3(1-2r). Cleavage StrengthTensile
9、 load required to cause separation of a 1-in. long metal-to-metal adhesive bond under the conditions set in ASTM D-1062. Climbing Drum Peel TestMethod for determining Peel Resistance of adhesive bond between a relatively flexible and a rigid material. (ASTM D-1781). Coefficient of ElasticityAn alter
10、nate term for Modulus of Elasticity. Cohesive StrengthTheoretical Stress that causes fracture in tensile test if material exhibits no plastic deformation. Complex ModulusMeasure of dynamic mechanical properties of a material, taking into account energy dissipated as heat during deformation and Recov
11、ery. It is equal to the sum of static modulus of a material and its loss modulus. In the case of shear loading, it is called dynamic modulus. CompressibilityExtent to which a material is compressed in test for compressibility and Recovery of gasket materials. It is usually reported with Recovery. Co
12、mpressibility and Recovery TestMethod for measuring behavior of gasket materials under short time compressive loading at room temperature. ASTM F-36 outlines a standard procedure. This test is not designed to indicate long term (creep) behavior and should not be confused with the plastometer test. C
13、ompressionTypically a direction of force applied to a sample to decrease its height Compression FatigueAbility of rubber to sustain repeated fluctuating compressive loads. (ASTM D-623) Compression setThe extent to which rubber is permanently deformed by a prolonged compressive load (ASTM D-395). Sho
14、uld not be confused with low temperature compression set. Compression testMethod for determining behavior of materials under crushing loads. Specimen is compressed, and deformation at various loads is recorded. Compressive stress and strain are calculated and plotted as a stress-strain diagram which
15、 is used to determine elastic limit, proportional limit, yield point, Yield Strength and (for some materials) compressive strength. Standard compression tests are given in ASTM C-773 (high strength ceramics), ASTM E-9 (metals), ASTM E-209 (metals at elevated temperatures) and ASTM D-695 (plastics).
16、Compression-Deflection TestNondestructive method for determining relationship between compressive load and deflection under load for specimen Compressive DeformationExtent to which a material deforms under a Crushing Load. Compressive StrengthMaximum stress a material can sustain under crush loading
17、. Compressive strength is calculated by dividing the maximum load by the original cross-sectional area of a specimen in a compression test. Compressive Yield StrengthStress which causes a material to exhibit a specified deformation. Usually it is determined from the stress-strain diagram obtained in
18、 a compression test. CreepDeformation that occurs over a period of time when a material is subjected to constant stress at constant temperature. In metals, creep usually occurs only at elevated temperatures. Creep at room temperature is more common in plastic materials and is called cold flow or def
19、ormation under load. Data obtained in a creep test usually is presented as a plot of creep vs. time with stress and temperature constant. Slope of the curve is creep rate and end point of the curve is Time for Rupture. As indicated in the accompanying diagram, the creep of a material can be divided
20、into three stages. First stage, or primary creep, starts at a rapid rate and slows with time. Second stage (secondary) creep has a relatively uniform rate. Third stage (tertiary) creep has an accelerating creep rate and terminates by failure of material at Time for Rupture. Creep LimitAlternate term
21、 for Creep Strength. Creep RateTime rate of deformation of a material subject to Stress at a constant temperature. It is the slope of the creep vs. time diagram obtained in a creep test. Units usually are in/in/hr or % of elongation/hr. Minimum creep rate is the slope of the portion of the creep vs.
22、 time diagram corresponding to secondary creep. Creep RecoveryRate of decrease in deformation that occurs when load is removed after prolonged application in a Creep Test. Constant temperature is maintained to eliminate effects of thermal expansion, and measurements are taken from time load is zero
23、to eliminate elastic effects. Creep Rupture StrengthStress required to cause fracture in a creep test within a specified time. Alternate term is Stress Rupture Strength. Creep StrengthMaximum Stress required to cause a specified amount of creep in a specified time. Also used to describe maximum Stre
24、ss that can be generated in a material at constant temperature under which creep rate decreases with time. An alternate term is creep limit. Creep TestMethod for determining creep or stress relaxation behavior. To determine creep properties, material is subjected to prolonged constant tension or com
25、pression loading at constant temperature. Deformation is recorded at specified time intervals and a creep vs. time diagram is plotted. Slope of curve at any point is creep rate. If failure occurs, it terminates test and Time for Rupture is recorded. If specimen does not fracture within test period,
26、creep recovery may be measured. To determine stress relaxation of material, specimen is deformed a given amount and decrease in stress over prolonged period of exposure at constant temperature is recorded. Standard creep testing procedures are detailed in ASTM E-139, ASTM D-2990 and D-2991 (plastics
27、) and ASTM D-2294 (adhesives). Crush ResistanceLoad required to produce fracture in a glass sphere subjected to crush loading. (ASTM D-1213). Crushing LoadMaximum compressive force applied during a compression or crushing test. For materials that do not shatter, crushing load is defined as the force
28、 required to produce a specified type of failure. Crushing StrengthCompressive load required to cause a crack to form in a sintered metal powder bearing (ASTM B-438 and B-439). Cold crushing strength of refractory bricks and shapes is the gross compressive Stress required to cause fracture. (ASTM C-
29、133). CompoundingThe combination of polymers with other materials either by means of mechanical (dry) blending or melt state blending CrossheadThis is the main beam on the testing machine. It is this beam that moves either up or down producing a compressive or tensile force. A grip is attached to th
30、e crosshead and the test piece is attached to the grip. The distance that the crosshead moves through is measured from a rotating optical sensor. Crosshead LoomA ribbon cable that connects the moving crosshead to the machine electronics, to supply the load cell with a voltage and supply the machine
31、with a load signal. D Deformation EnergyEnergy required to deform a material a specified amount. It is the area under the Stress-Strain Diagram up to a specified strain. Deformation Under LoadMeasure of the ability of rigid plastics to withstand permanent deformation and the ability of nonrigid plas
32、tics to return to original shape after deformation. Standard test methods for determining both types of deformation under load are given in ASTM D-621. For rigid plastics, deformation is re-ported as % change in height of specimen after 24 hours under a specified load. For nonrigid plastics, results
33、 are reported as % change in height after 3 hours under load and Recovery in the 1-1/2 hour period following removal of the load. Recovery is % increase in height calculated on basis of original height. Delamination StrengthMeasure of the node-to-node Bond Strength of honeycomb core materials. It is
34、 equal to the tensile load applied to a honeycomb panel at fracture divided by its width times its thickness. (ASTM C-363) DenierThe unit of linear density equal to the mass in grams per 9000 m of fiber, yarn, or other textile strand. Dry StrengthStrength of an adhesive joint determined immediately
35、after drying or after a period of conditioning in a specified atmosphere. (ASTM D-2475) DuctilityExtent to which a material can sustain plastic deformation without rupture. Elongation and Reduction of Area are common indices of ductility. Dynamic CreepCreep that occurs under fluctuating load or temp
36、erature. Die swellWhenever a polymer melt emerges from a die the diameter or thickness is always larger than the diameter (or gap) of the die.At usual production throughputs,diameter or thickness ratios range from 1.20-1.40 for PVC to 1.50-2.00 for commercial grade Polyethyenes and much more for som
37、e polymers containing a high molecular weight tail.It is an indication of the elasticity of the polymer.The more elastic polymers give larger swell.Of course,by pulling the extrudates the swell is reduced and of course extrudates can be drawn down to diameters(or thickness) much smaller than the die
38、 diameter or gap. DiameterUsed where the cross section shape of the test piece is round. E EASL(Elongation at a specified load) Eccentricity of LoadingDistance between the actual line of action of compressive or tensile loads and the line of action that would produce a uniform Stress over the cross
39、section of the specimen. Edge Tearing StrengthMeasure of the resistance of paper to tearing when folded over a V-notch beam and loaded in a tensile testing machine. Results are re-ported in lb or kg. (See Tear Resistance) Elastic HysteresisDifference between strain energy required to generate a give
40、n Stress in a material and elastic energy at that Stress. It is the energy dissipated as heat in a material in one cycle of dynamic testing. Elastic hysteresis divided by elastic deformation energy is equal to damping capacity. Elastic LimitGreatest Stress that can be applied to a material without c
41、ausing permanent deformation. For metals and other materials that have a significant straight line portion in their Stress/strain diagram, elastic limit is approximately equal to proportional limit. For materials that do not exhibit a significant proportional limit, elastic limit is an arbitrary app
42、roximation (the apparent elastic limit). Elastic Limit, ApparentArbitrary approximation of the elastic limit of materials that do not have a significant straight line portion on a Stress/strain diagram. It is equal to the Stress at which the rate of strain is 50% greater than at zero Stress. It is t
43、he Stress at the point of tangency between the Stress-Elastic Hysteresis strain curve and the line having a slope, with respect to the Stress axis, 50% greater than the slope of the curve at the origin. ElasticityAbility of a material to return to its original shape when load causing deformation is
44、removed. ElongationMeasure of the ductility of a material determined in a Tensile Test. It is the increase in gage length (measured after rupture) divided by original gage length. Higher elongation indicates higher ductility. Elongation cannot be used to predict behavior of materials subjected to su
45、dden or repeated loading. EmbrittlementReduction in ductility due to physical or chemical changes. EnduranceAlternate term for Fatigue Limit. Engineering StressLoad applied to a specimen in a tension or compression test divided by the cross-sectional area of the specimen. The change in cross-section
46、al area that occurs with increases and decreases in applied load, is disregarded in computing engineering Stress. It is also called conventional Stress. ExtensometerInstrument for measuring changes in linear dimensions. Also called a Strain gauge. Frequently based on Strain gauge technology. Eye End
47、An adapter that fits to a load cell or machine, that enables grip or jigs to be attached F FatiguePermanent structural change that occurs in a material subjected to fluctuating Stress and strain. However, in the case of glass, fatigue is determined by long-term static testing and is analogous to Str
48、ess rupture in other materials. In general, fatigue failure can occur with Stress levels below the elastic limit. Fatigue LifeNumber of cycles of fluctuating Stress and strain of a specified nature that a material will sustain before failure occurs. Fatigue life is a function of the magnitude of the
49、 fluctuating Stress, geometry of the specimen and test conditions. An S-N diagram is a plot of the fatigue life at various levels of fluctuating Stress. Fatigue LimitMaximum fluctuating Stress a material can endure for an infinite number of cycles. It is usually determined from an S-N diagram and is equal to the Stress corresponding to the asymptote of the locus of points corresponding to the fatigue life of a number of fatigue test specimens. An alternate term is endurance limit. Fatigue Notch FactorRatio of fatigue strengt
