ISO/TR 25679:2005

TECHNICAL ISO/TR
REPORT 25679
First edition
2005-11-15

Mechanical testing of metals — Symbols
and definitions in published standards
Essais mécaniques des métaux — Symboles et définitions figurant
dans les normes publiées




Reference number
ISO/TR 25679:2005(E)
©
ISO 2005

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ISO/TR 25679:2005(E)
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ISO/TR 25679:2005(E)
Contents Page
Foreword. v
Introduction . vi
1 Scope . 1
2 Designation system. 1
3 Definitions and symbols . 3
3.1 Code 1.01 Metallic materials — Uninterrupted uniaxial creep testing in tension-method of
test. 4
3.1.1 Definitions . 4
3.2 Code 1.02 Metallic materials — Calibration of force-proving instruments used for the
verification of uniaxial testing machines . 6
3.3 Code 1.03 Metallic materials — Tensile testing at elevated temperature . 7
3.3.1 Definitions . 7
3.4 Code 1.04 Metallic materials — Tensile testing. 9
3.4.1 Definitions . 9
3.5 Code 1.05 Metallic materials — Verification of static uniaxial tensile testing machines. 12
3.5.1 Definitions . 12
3.6 Code 1.06 Metallic materials — Verification of static uniaxial testing machines — tension
creep testing machines. 13
3.7 Code 1.07 Metallic materials — Calibration of extensometers used in uniaxial testing . 14
3.8 Code 1.08 Metallic materials — Tensile testing at low temperature. 14
3.8.1 Definitions . 14
3.9 Code 1.09 Metallic materials — Tensile testing in liquid helium . 16
3.9.1 Definitions . 16
3.10 Code 2.01 Metallic materials — Bend test.17
3.11 Code 2.02 Metallic materials — Sheet and strip 3 mm thick or less — Reverse bend test. 18
3.12 Code 2.03 Metallic materials — Wire — Simple torsion test . 18
3.13 Code 2.04 Metallic materials — Wire — Reverse bend test. 18
3.14 Code 2.06 Metallic materials — Sheet and strip — Modified Erichsen cupping test. 19
3.15 Code 2.07 Metallic materials — Tube (in full section) — Bend test. 19
3.16 Code 2.08 Metallic materials — Tube — Flattening test . 19
3.17 Code 2.09 Metallic materials — Tube — Drift expanding test. 20
3.18 Code 2.10 Metallic materials — Tube — Flanging test . 20
3.19 Code 2.11 Metallic materials — Tube — Ring expanding test . 20
3.20 Code 2.13 — Metallic materials — Wire — Reverse torsion test . 21
3.21 Code 2.14 Metallic materials — Sheet and strip — Determination of plastic strain ratio . 21
3.21.1 Definitions . 21
3.22 Code 2.15 Metallic materials — Sheet and strip — Determination of tensile strain
hardening exponent. 21
3.23 Code 2.16 Metallic materials — Earing test . 22
3.24 Code 2.17 Metallic materials — Guidelines for the determination of forming-limit diagrams. 23
3.25 Code 2.18 Metallic materials — Tube ring hydraulic pressure test. 23
3.26 Code 2.19 Metallic materials — Strain analysis report . 23
3.27 Code 3.01 Metallic materials — Hardness test — Knoop test. 24
3.28 Code 3.02 Metallic materials — Brinell hardness test — Part 1: Test method. 24
3.29 Code 3.03 Hardness test — Vickers hardness test — Part 1: Test method. 25
3.30 Code 3.04 Metallic materials — Rockwell Hardness test — Part 1: Test method (scales A-
B-C-D-E-F-G-H-K-N-T). 25
3.31 Code 3.06 Metallic materials — Instrumented indentation test for hardness and materials
parameters — Part : Test method . 26
3.32 Code 4.01 Charpy impact test (U-notch) .27
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ISO/TR 25679:2005(E)
3.33 Code 4.01 Metallic materials — Charpy pendulum impact test — Part 1: Test method . 27
3.33.1 Definitions. 27
3.34 Code 4.01 Metallic materials — Charpy pendulum impact test — Part 2: Verification of test
machines. 28
3.34.1 Definitions. 28
3.35 Code 4.01 Metallic materials — Charpy pendulum impact test — Part 3: Preparation and
characterization of Charpy V reference test pieces for verification of test machines . 30
3.36 Code 4.03 — Metallic materials –Determination of the plane-strain fracture toughness. 30
3.36.1 Definitions. 30
3.37 Code 4.04 Steel — Charpy V-notch pendulum impact test — Instrumented test method. 31
3.37.1 Definitions. 31
3.38 Code 4.05 Metallic materials — Unified method of test for the determination of quasistatic
fracture toughness. 32
3.38.1 Definitions. 32
3.39 Code 5.01 Metals — Axial load fatigue testing. 35
3.40 Code 5.01 Metalic materials — Fatigue testing — Axial force controlled method. 36
3.41 Code 5.02 Metals — Rotating bar bending fatigue testing . 37
3.42 Code 5.03 Steel —Torsional stress fatigue testing . 37
3.43 Code 5.04 Axial load fatigue machines — Dynamic force calibration — Strain gauge
technique . 37
3.44 Code 5.05 Metallic materials — Fatigue testing — Axial-strain-controlled method. 38
3.44.1 Definitions. 38
3.45 Code 5.06 Metallic materials — Fatigue testing — Statistical planning and analysis of data . 40
3.45.1 Definitions. 40
3.46 Code 5.07 Metallic materials — Fatigue testing — Fatigue crack growth method. 40
3.46.1 Definitions. 40
4 Concordance of Keywords Scope. 43
5 Alphabetical listing of symbols . 47
Annex A Index . 63

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ISO/TR 25679:2005(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies
(ISO member bodies). The work of preparing International Standards is normally carried out through ISO
technical committees. Each member body interested in a subject for which a technical committee has been
established has the right to be represented on that committee. International organizations, governmental and
non-governmental, in liaison with ISO, also take part in the work. ISO collaborates closely with the
International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 2.
The main task of technical committees is to prepare International Standards. Draft International Standards
adopted by the technical committees are circulated to the member bodies for voting. Publication as an
International Standard requires approval by at least 75 % of the member bodies casting a vote.
In exceptional circumstances, when a technical committee has collected data of a different kind from that
which is normally published as an International Standard (“state of the art”, for example), it may decide by a
simple majority vote of its participating members to publish a Technical Report. A Technical Report is entirely
informative in nature and does not have to be reviewed until the data it provides are considered to be no
longer valid or useful.
Attention is drawn to the possibility that some of the elements of this document may be the subject of patent
rights. ISO shall not be held responsible for identifying any or all such patent rights.
ISO/TR 25679 was prepared by Technical Committee ISO/TC 164, Mechanical testing of metals.
1)
This first edition of ISO/TR 25679, together with ISO 23718 , Metallic materials — Terms used in mechanical
testing, cancel and replace ISO/TR 12735-1:1996, Mechanical testing of metals — Symbols used with their
definitions — Part 1: Symbols and definitions in published standards.

1) In preparation.
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ISO/TR 25679:2005(E)
Introduction
This index of symbols and definitions in published standards has been prepared to provide an appropriate
means for avoiding contradictions and misunderstandings and to standardize various kinds of symbols and
their definitions generally used in this field. Wherever possible, the same symbol has been used to denote the
same type of parameter in the different tests, but the differing types of test piece, product form and test have
to be taken into account. This has not been universally possible and symbols should always be considered in
the context of the specific method of test being used.
In the discussion of revising ISO/TR 12735-1:1996, common terms among the published standards were
selected and a Draft International Standard covering terminology: ISO/DIS 23718, Metallic materials — Terms
used in mechanical testing, was prepared. This Technical Report, which is an index of symbols and definitions,
was separated from the terminology (ISO/DIS 23718) in order to be updated flexibly in future.

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TECHNICAL REPORT ISO/TR 25679:2005(E)

Mechanical testing of metals — Symbols and definitions in
published standards
1 Scope
This Technical Report enumerates the symbols and definitions used in International Standards for specific
methods of mechanical testing of metallic materials, which are the responsibility of ISO Technical Committee
164, Mechanical testing of metals. The data is indexed alphabetically and via a coding system. Annex A
provides an additional cross-reference between the coding system and relevant International Standard
numbers.
2 Designation system
To assist in indexing and cross-referencing symbols and definitions, a code number is used to identify test
methods. The first digit of the code identifies the sub-committee of ISO/TC 164 that is responsible for
preparing and reviewing International Standards for that test method. Subsequent digits are in ascending
order of the ISO number for each International Standard or Draft International Sandard.
International Standards that relate to a common test method and which all share the same set of symbols and
definitions are given a single code number.
If there existed both a valid International Standard and a document designed to replace it that had reached the
DIS stage, then both the International Standard and the DIS (Draft International Sandard) or FDIS will have
been assigned to the same code number.
Each test method for metallic materials is identified and designated as shown in Table 1. Annex A provides a
rapid cross-reference to the coding system.
Table 1 — Identity and code of mechanical test
Test Identity Code ISO standards
SC 1 Metallic materials — Uninterrupted uniaxial creep testing in tension — Method of 1.01 204:1997
test
DIS 204:2005
Metallic materials — Calibration of force-proving instruments used for the 1.02 376:2004
verification of uniaxial testing machines
Metallic materials — Tensile testing at elevated temperature 1.03 783:1999
Metallic materials — Tensile testing at ambient temperature 1.04 6892:1998
Metallic materials — Verification of static uniaxial testing machines — Part 1: 1.05 7500-1:2004
Tension/compression testing machines — Verification and calibration of the force-
measuring system
1.06 7500-2:1996
Metallic materials — Verification of static uniaxial testing machines — Part 2:
Tension creep testing machines — Verification of the applied load
DIS 7500-2:2005
Metallic materials — Calibration of extensometers used in uniaxial testing 1.07 9513:1999
Metallic materials — Tensile testing at low temperature 1.08 15579:2000
Metallic materials — Tensile testing in liquid helium 1.09 19819:2004
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ISO/TR 25679:2005(E)
Table 1 (continued)
Test Identity Code ISO standards
SC 2 Metallic materials — Bend test 2.01 7438:2005
Metallic materials — Sheet and strip 3 mm thick or less — Reverse bend test 2.02 7799:1985
Metallic materials — Wire — Simple torsion test 2.03 7800:2003
Metallic materials — Wire — Reverse bend test 2.04 7801:1984
*Metallic materials — Wire — Wrapping test 2.05 7802:1983
Metallic materials — Sheet and strip — Erichsen cupping test 2.06 20482:2003
Metallic materials — Tube (in full section) — Bend test 2.07 8491:1998
Metallic materials — Tube — Flattening test 2.08 8492:1998
Metallic materials — Tube — Drift-expanding test 2.09 8493:1998
Metallic materials — Tube — Flanging test 2.10 8494:1998
Metallic materials — Tube — Ring-expanding test 2.11 8495:1998
*Metallic materials — Tube — Ring tensile test 2.12 8496:1998
Metallic materials — Wire — Reverse torsion test 2.13 9649:1990
Metallic materials — Sheet and strip — Determination of plastic strain ratio 2.14 10113:1991
DIS 10113:2005
Metallic materials — Sheet and strip — Determination of tensile strain hardening 2.15 10275:1993
exponent
Metallic materials — Earing test 2.16 11531:1994
Metallic materials — Guidelines for the determination of forming-limit diagrams 2.17 12004:1997
Metallic materials — Tube ring hydraulic pressure test 2.18 15363:2000
Metallic materials — Strain analysis report 2.19 TR 14936:1998
SC 3 Metallic materials — Hardness test — Knoop test 3.01 4545:1993
FDIS 4545-1 to
4545-4:2005
*Metallic materials — Hardness test — Verification of Knoop hardness testing 3.01 4546:1993
machines
*Metallic materials — Hardness test — Calibration of standardized blocks to be 3.01 4547:1993
used for Knoop hardness testing machines
Metallic materials — Brinell hardness test — Part 1: Test method 3.02 6506-1:1999
FDIS 6506-1:2005
*Metallic materials — Brinell hardness test — Part 2: Verification and calibration of 3.02 6506-2:1999
testing machines FDIS 6506-2:2005
*Metallic materials — Brinell hardness test — Part 3: Calibration of reference 3.02 6506-3:1999
blocks FDIS 6506-3:2005
Metallic materials — Vickers hardness test — Part 1: Test method 3.03 6507-1:1997
FDIS 6507-1:2005
*Metallic materials — Vickers hardness test — Part 2: Verification of testing 3.03 6507-2:1997
machines FDIS 6507-2:2005
*Metallic materials — Vickers hardness test — Part 3: Calibration of reference 3.03 6507-3:1997
blocks FDIS 6507-3:2005
Metallic materials — Rockwell hardness test — Part 1: Test method (scales A, B, 3.04 6508-1:1999
C, D, E, F, G, H, K, N, T) FDIS 6508-1:2005

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ISO/TR 25679:2005(E)
Table 1 (continued)
Test Identity Code ISO standards
*Metallic materials — Rockwell hardness test — Part 2: Verification and calibration 3.04 6508-2:1999
of testing machines (scales A, B, C, D, E, F, G, H, K, N, T) FDIS 6508-2:2005
*Metallic materials —Rockwell hardness test — Part 3: Calibration of reference 3.04 6508-3:1999
blocks (scales A, B, C, D, E, F, G, H, K, N, T) FDIS 6508-3:2005
*Metallic materials — Hardness testing — Tables of Knoop hardness values for 3.05 10250:1994
use in tests made on flat surfaces
Metallic materials — Instrumented indentation test for hardness and materials 3.06 14577-1:2002
parameters — Part 1: Test method
*Metallic materials — Instrumented indentation test for hardness and materials 3.06 14577-2:2002
parameters — Part 2: Verification and calibration of testing machines
*Metallic materials — Instrumented indentation test for hardness and materials 3.06 14577-3:2002
parameters — Part 3: Calibration of reference blocks
*Metallic materials — Conversion of hardness values 3.07 18265:2003
SC 4 Steel — Charpy impact test (U-notch) 4.01 83:1976
*Steel — Charpy impact test (V-notch) 4.01 148:1983
Metallic materials — Charpy pendulum impact test — Part 1: Test method 4.01 FDIS 148-1:2005
Metallic materials — Charpy pendulum impact test — Part 2: Verification of test 4.01 148-2:1998
machines
Metallic materials — Charpy pendulum impact test — Part 3: Preparation and 4.01 148-3:1998
characterization of Charpy V reference test pieces for verification of test machines
*Steel — Designation of test piece axes 4.02 3785:1976
FDIS 3785:2005
Metallic materials — Determination of plane-strain fracture toughness 4.03 12737:2005
Steel — Charpy V-notch pendulum impact test — Instrumented test method 4.04 14556:2000
Metallic materials — Unified method of test for the determination of quasistatic 4.05 12135:2002
fracture toughness
SC 5 Metals — Axial load fatigue testing 5.01 1099:1975
Metallic materials — Fatigue testing — Axial force controlled method 5.01 DIS 1099:2005
Metals — Rotating bar bending fatigue testing 5.02 1143:1975
Steel — Torsional stress fatigue testing 5.03 1352:1977
Axial load fatigue testing machines — Dynamic force calibration — Strain gauge 5.04 4965:1979
technique
Metallic materials — Fatigue testing — Axial-strain-controlled method 5.05 12106:2003
Metallic materials — Fatigue testing — Statistical planning and analysis of data 5.06 12107:2003
Metallic materials — Fatigue testing — Fatigue crack growth method 5.07 12108:2002
* There are no symbols or definitions in the text of the standard.
3 Definitions and symbols
Definitions and symbols employed in all of the International Standards and (Final) Draft International
Standards prepared by ISO/TC 164, Mechanical testing of metals are classified under the codes listed in
Table 1, Identity and code of mechanical test. If a standard has separate clauses for definitions and symbols,
the definitions are listed first, followed by a table of symbols. Each table of symbols is re-arranged into a
consistent alphabetical order. For clarity, notes, alternative definitions and conditions embodied within
definitions, which are particular to the individual standard, are excluded.
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ISO/TR 25679:2005(E)
3.1 Code 1.01 Metallic materials — Uninterrupted uniaxial creep testing in tension —
Method of test
3.1.1 Definitions
reference length, L
r
base length used for the calculation of elongation
NOTE Examples of reference lengths for several types of test pieces are given.
original reference length, L
ro
reference length determined at ambient temperature before the test L , not exceeding the parallel length L
ro c
by more than 10 % L for circular test pieces, or by more than 15 % L for square or rectangular test pieces
c c
final reference length, L
ru
reference length determined at ambient temperature after rupture, the two pieces having been carefully fitted
back together so that their axes lie in a straight line
original gauge length, L
o
length between gauge length marks on the piece measured at ambient temperature before the test
final gauge length after rupture, L
u
length between gauge marks on the test piece measured after rupture, at ambient temperature, the two pieces
having been carefully fitted back together so that their axes lie in a straight line
parallel length, L
c
length of the parallel reduced section of the test piece
extensometer gauge length, L
e
distance between the measuring points of the extensometer; as near as possible to the reference length
original cross-sectional area, S
o
cross-sectional area of the parallel length determined at ambient temperature prior to testing
minimum cross-sectional area after rupture, S
u
minimum cross-sectional area of the parallel length determined at ambient temperature after rupture, the two
pieces having been carefully fitted back together so that their axes lie in a straight line
initial stress, σ
o
applied force divided by the original cross-sectional area S of the test piece
o
elongation
increase of the reference length at any moment during the test
percentage creep elongation, A
f
at any given moment t during the test, the increase in the reference length between this moment and the zero
moment (∆L ) at a specified temperature, expressed as a percentage of the original reference length
rt
∆L
rt

A =×100
f
L
ro
NOTE 1 The symbol A may have as superscript the specified temperature T, in degrees Celsius, and as subscript the
f
stress, in megapascals, and the time t, in hours.
NOTE 2 By convention, the zero moment (start of time) is the moment at which the initial stress (σ ) is applied to the
o
test piece. The origin of the elongation is the value of the reference length at the zero moment.
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ISO/TR 25679:2005(E)
percentage elongation after creep rupture, A
fu
permanent elongation of the reference length after rupture (L − L ), expressed as a percentage of the
ru ro
original reference length:
LL -
ru ro
A=×100
fu
L
ro
NOTE The symbol A may have as superscript the specified temperature T, in degrees Celsius, and as subscript the
fu
stress, in megapascals.
percentage reduction of area after creep rupture, Z
u
maximum change in cross-sectional area measured after rupture (S − S ), expressed as a percentage of the
o u
original cross-sectional area (S ):
o
SS−
ou
Z=×100
u
S
o
NOTE The symbol Z may have as superscript the specified temperature T, in degrees Celsius, and as subscript the
u
stress, in megapascals.
creep rupture time, t
u
time required for the test piece, maintained at the specified temperature T and strained by the specified tensile
force, to rupture
NOTE The symbol t may have as superscript the specified temperature T, in degrees Celsius, and as subscript the
u
stress, in megapascals.
simple machine
test machine that allows the straining of only one test piece at a time
multiple machine
test machine that allows simultaneous straining of more than one test piece at the same temperature
Table 2 — Symbols designated in the International Standard, Code 1.01
Symbol Unit Meaning
∆L mm Increase in the reference length between a moment t and the zero moment
rt
σ MPa Initial stress
o
A % Percentage creep elongation
f
A % Percentage elongation after creep rupture
fu
b mm Width of the cross-section of the parallel length of a test piece of square or rectangular
cross-section
d mm Diameter of the cross-section of the parallel length of a cylindrical test piece
L mm Parallel length
c
L mm Extensometer gauge length
e
L mm Original gauge length
o
L mm Reference length
r
L mm Original reference length
ro
L mm Final reference length
ru
L mm Final gauge length after rupture
u

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ISO/TR 25679:2005(E)
Table 2 (continued)
Symbol Unit Meaning
r mm Transition radius
2
S mm Original cross-sectional area of the parallel length
o
2
S mm Minimum cross-sectional area after rupture
u
T °C Specified temperature
T °C Indicated temperature
i
t h Creep rupture time
u
Z % Percentage reduction of area after creep rupture
u
3.2 Code 1.02 Metallic materials — Calibration of force-proving instruments used for the
verification of uniaxial testing
...