SIST EN ISO 6507-1:2018

SLOVENSKI STANDARD
oSIST prEN ISO 6507-1:2016
01-oktober-2016
Kovinski materiali - Preskus trdote po Vickersu - 1. del: Preskusni postopek
(ISO/DIS 6507-1:2016)
Metallic materials - Vickers hardness test - Part 1: Test method (ISO/DIS 6507-1:2016)
Metallische Werkstoffe - Härteprüfung nach Vickers - Teil 1: Prüfverfahren (ISO/DIS
6507-1:2016)
Matériaux métalliques - Essai de dureté Vickers - Partie 1: Méthode d'essai (ISO/DIS
6507-1:2016)
Ta slovenski standard je istoveten z: prEN ISO 6507-1
ICS:
77.040.10 Mehansko preskušanje kovin Mechanical testing of metals
oSIST prEN ISO 6507-1:2016 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN ISO 6507-1:2016

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oSIST prEN ISO 6507-1:2016
DRAFT INTERNATIONAL STANDARD
ISO/DIS 6507-1
ISO/TC 164/SC 3 Secretariat: DIN
Voting begins on: Voting terminates on:
2016-07-12 2016-10-03
Metallic materials — Vickers hardness test —
Part 1:
Test method
Matériaux métalliques — Essai de dureté Vickers —
Partie 1: Méthode d’essai
ICS: 77.040.10
ISO/CEN PARALLEL PROCESSING
This draft has been developed within the International Organization for
Standardization (ISO), and processed under the ISO lead mode of collaboration
as defined in the Vienna Agreement.
This draft is hereby submitted to the ISO member bodies and to the CEN member
bodies for a parallel five month enquiry.
THIS DOCUMENT IS A DRAFT CIRCULATED
FOR COMMENT AND APPROVAL. IT IS
THEREFORE SUBJECT TO CHANGE AND MAY
NOT BE REFERRED TO AS AN INTERNATIONAL
STANDARD UNTIL PUBLISHED AS SUCH.
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Reference number
NATIONAL REGULATIONS.
ISO/DIS 6507-1:2016(E)
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TO SUBMIT, WITH THEIR COMMENTS,
NOTIFICATION OF ANY RELEVANT PATENT
RIGHTS OF WHICH THEY ARE AWARE AND TO
©
PROVIDE SUPPORTING DOCUMENTATION. ISO 2016

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Contents Page
Foreword .iv
1 Scope.1
2 Normative references .1
3 Principle .1
4 Symbols, abbreviated terms, and designations .2
4.1 Symbols and abbreviated terms used in this document .2
4.2 Designation of hardness number .3
5 Testing machine .3
5.1 Testing machine .3
5.2 Indenter .3
5.3 Diagonal measuring system.4
6 Test piece .4
6.1 Test surface.4
6.2 Preparation .4
6.3 Thickness .4
6.4 Tests on curved surfaces .5
6.5 Support of unstable test pieces.5
7 Procedure.5
7.1 Test temperature .5
7.2 Test force .5
7.3 Daily verification .5
7.4 Test piece support .6
7.5 Focus on test surface .6
7.6 Test force application .6
7.7 Prevention of the effect of shock or vibration.6
7.8 Minimum distance between adjacent indentations.6
7.9 Measurement of the diagonal length.7
7.10 Calculation of hardness value .7
8 Uncertainty of the results .8
9 Test report .8
Annex A (normative) Minimum thickness of the test piece in relation to the test force and to the
hardness .9
Annex B (normative) Tables of correction factors for use in tests made on curved surfaces . 11
Annex C (normative) Procedure for periodic checking of the testing machine and the diagonal
measuring system by the user . 15
Annex D (informative) Uncertainty of the measured hardness values. 16
Annex E (informative) Vickers hardness measurement traceability . 22
Annex F (informative) CCM - Working Group on Hardness . 25
Annex G (informative) Adjustment of Köhler illumination systems . 26
Bibliography . 27


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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.
The procedures used to develop this document and those intended for its further maintenance are described
in the ISO/IEC Directives, Part 1. In particular the different approval criteria needed for the different types of
ISO documents should be noted. This document was drafted in accordance with the editorial rules of the
ISO/IEC Directives, Part 2 (see www.iso.org/directives).
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. Details of any patent
rights identified during the development of the document will be in the Introduction and/or on the ISO list of
patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation on the meaning of ISO specific terms and expressions related to conformity assessment,
as well as information about ISO's adherence to the WTO principles in the Technical Barriers to Trade (TBT)
see the following URL: Foreword - Supplementary information
ISO 6507-1 was prepared by Technical Committee ISO/TC 164, Mechanical testing of metals, Subcommittee
SC 3, Hardness testing.
This second edition cancels and replaces the first edition (ISO 6507-4:2005), which has been technically
revised.
ISO 6507 consists of the following parts, under the general title Metallic materials — Vickers hardness test:
 Part 1: Test method
 Part 2: Verification and calibration of testing machines
 Part 3: Calibration of reference blocks
 Part 4: Tables of hardness values


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oSIST prEN ISO 6507-1:2016
DRAFT INTERNATIONAL STANDARD ISO/DIS 6507-1:2016(E)

Metallic materials — Vickers hardness test — Part 1: Test
method
1 Scope
This part of ISO 6507 specifies the Vickers hardness test method, for the three different ranges of test force
for metallic materials including hardmetals (see Table 1).
Table 1 — Ranges of test force
Ranges of test force, F
Hardness symbol Designation
N
F ≥ 49,03 ≥ HV 5 Vickers hardness test
Low -force Vickers hardness test
1,961 ≤ F  49,03 HV 0,2 to  HV 5
Vickers microhardness test
0,009 807 ≤ F  1,961 HV 0,001 to  HV 0,2

The Vickers hardness test is specified in this part of ISO 6507 for lengths of indentation diagonals between
0,020 mm and 1,400 mm.
For specific materials and/or products, particular International Standards exist.
2 Normative references
The following referenced documents are indispensable for the application of this document. For dated
references, only the edition cited applies. For undated references, the latest edition of the referenced
document (including any amendments) applies.
ISO 6507-2, Metallic materials — Vickers hardness test — Part 2: Verification and calibration of testing
machines
ISO 6507-3, Metallic materials — Vickers hardness test — Part 3: Calibration of reference blocks
ISO 6507-4, Metallic materials — Vickers hardness test — Part 4: Tables of hardness values
3 Principle
A diamond indenter, in the form of a right pyramid with a square base and with a specified angle between
opposite faces at the vertex, is forced into the surface of a test piece followed by measurement of the diagonal
length of the indentation left in the surface after removal of the test force, F (see Figure 1).
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Figure 1 — Principle of the test, geometry of indenter and Vickers indentation
The Vickers hardness is proportional to the quotient obtained by dividing the test force by the area of the
sloped surface of indentation, which is assumed to be a right pyramid with a square base, and having at the
vertex the same angle as the indenter.
4 Symbols, abbreviated terms, and designations
4.1 Symbols and abbreviated terms used in this document
See Table 2 and Figure 1.

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Table 2 — Symbols and abbreviated terms
Symbol/
Designation
Abbreviated
term
Angle betw een the opposite faces at the vertex of the pyramidal indenter (nominally 136) (see Figure 1)

F Test force, in new tons (N)
d Arithmetic mean, in millimetres, of the tw o diagonal lengths d and d (see Figure 1)
1 2
V Magnification of the measuring system
Test Force (kgf)
Vickers hardness =
2
Surface area of indentation (mm )
1 Test Force (N)
= ×
2
g Surface area of indentation (mm )
𝑛
𝛼
2 𝐹 sin
HV
1 𝐹 1
2
= × = ×
𝛼
2
2
g ⁄( ) g 𝑑
𝑑 2 sin
𝑛 𝑛
2
For the nominal angle α = 136°,
𝐹
Vickers hardness ≈ 0,1891 ×
2
𝑑
2
NOTE 1 Standard acceleration due to gravity, g = 9,806 65 m/s which is the conversion factor from kgf to N
𝑛
NOTE 2 To reduce uncertainty, the Vickers hardness may be calculated using the actual indenter angle 

4.2 Designation of hardness number
Vickers hardness, HV, is designated as shown in the following example.

5 Testing machine
5.1 Testing machine
The testing machine shall be capable of applying a predetermined force or forces within the desired range of
test forces, in accordance with ISO 6507-2.
5.2 Indenter
The indenter shall be a diamond in the shape of a right pyramid with a square base, as specified in ISO 6507-
2.
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5.3 Diagonal measuring system
The diagonal measuring system shall satisfy the specifications in ISO 6507-2.
Many older objectives lenses are non-linear towards the edge of the field of view. Therefore, magnifications
should be provided so that the diagonal can be enlarged to greater than 25 % but less than 75 % of the
maximum possible optical field of view.
NOTE Systems using a camera for measurement may use 100% of the camera’s field of view provided they are
designed to consider the 75% and any other field of view limitations of the optical system.
The resolution required of the diagonal measuring system depends on the size of the smallest indentation to
be measured.
The scale of the measuring system shall be graduated to permit estimation of the diagonals of the indentation
in accordance with Table 3.
Table 3 – Resolution of the measuring system
Diagonal length, d
Resolution of the measuring system
mm
0,000 4 mm
d  0,080
0,080 ≤ d 0,5 % of d
NOTE The diagonal length of the indentation determines the necessary
magnification V of the measuring system according to the following condition:
V  d ≥ 14 mm
For indentation diagonals d  0,035 mm this condition may not be fulfilled, but the
magnification should be at least  400.

The resolution of the measuring system for Vickers hardness testing of hardmetals is specified in ISO 3878
[11].
6 Test piece
6.1 Test surface
The test shall be carried out on a surface which is smooth and even, free from oxide scale, foreign matter and,
in particular, completely free from lubricants, unless otherwise specified in product standards. The finish of the
surface shall permit accurate determination of the diagonal length of the indentation.
6.2 Preparation
Surface preparation shall be carried out in such a way that any pull out of materials, or alteration of the
surface hardness due to excessive heating or cold-working, for example, is minimized.
Due to the small depth of Vickers microhardness indentations, it is essential that special precautions be taken
during preparation. It is recommended to use a polishing/electropolishing process which is suitable for the
material to be measured.
6.3 Thickness
The thickness of the test piece, or of the layer under test, shall be at least 1,5 times the diagonal length of the
indentation (see Annex A). No deformation shall be visible at the back of the test piece after the test.
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NOTE The depth of the indentation is approximately 1/7 of the diagonal length (0,143 d).
6.4 Tests on curved surfaces
For tests on curved surfaces, the corrections given in Annex B, Tables B.1 to B.6 shall be applied.
6.5 Support of unstable test pieces
For test pieces of small cross-section or of irregular shape, it may be necessary to provide some form of
additional mounting in plastic material. The test piece shall be adequately supported by the mounting medium
so that the test piece does not move during the force application.
7 Procedure
7.1 Test temperature
In general, the test is carried out at ambient temperature within the limits of 10 °C to 35 °C. If the test is
carried out at a temperature outside this range, it shall be noted in the test report. Tests carried out under
controlled conditions shall be made at a temperature of (23  5) °C.
7.2 Test force
The test forces given in Table 4 are typical. Other test forces may be used. Test forces should be chosen that
result in indentations with diagonals greater than 0,020 mm.
Table 4 — Typical Test forces
a
Hardness test Low-force hardness test Microhardness test
Nominal value of Nominal value of Nominal value of
Hardness Hardness Hardness
the test force F the test force F the test force F
symbol symbol symbol
N N N
a
--- --- --- --- HV 0,001 0,009 807
--- --- --- --- HV 0,002 0,019 61
--- --- --- --- HV 0,003 0,029 42
--- --- --- --- HV 0,005 0.049 03
HV   5 49,03 HV 0,2 1,961 HV 0,01  0,098 07
HV  10 98,07 HV 0,3 2,942 HV 0,015 0,147
HV  20 196,1 HV 0,5 4,903 HV 0,02  0,196 1
HV  30 294,2 HV 1  9,807 HV 0,025 0,245 2
HV  50 490,3 HV 2  19,61 HV 0,05  0,490 3
a
HV 100 980,7 HV 3  29,42 HV 0,1   0,980 7
a
Nominal test forces greater than 980,7 N or smaller than 0,009 807 N may be applied.

7.3 Daily verification
The daily verification defined in Annex C shall be performed before the first test of each week for each test
force used but is recommended daily. The daily verification is recommended whenever the test force is
changed. The daily verification shall be done whenever the indenter is changed. The daily verification should
be done within 200 HV of the expected hardness level to be tested.
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7.4 Test piece support
The test piece shall be placed on a rigid support. The support surfaces shall be clean and free from foreign
matter (scale, oil, dirt, etc.). It is important that the test piece lies firmly on the support so that displacement
cannot occur during the test.
7.5 Focus on test surface
Focus the diagonal measuring system microscope so that the specimen surface and the desired test location
can be observed.
NOTE Some testers do not require that the microscope be focused on the specimen surface.
7.6 Test force application
Bring the indenter into contact with the test surface and apply the test force in a direction perpendicular to the
surface, without shock, vibration or overload, until the applied force attains the specified value. The time from
+1
the initial application of the force until the full test force is reached shall be 7 s.
−5
+1
NOTE 1 The requirements for the time durations are given w ith asymmetric limits. For example, 7 s indicates that 7 s
−5
is the nominal time duration, w ith an acceptable range of not less than 2 s (7 s – 5 s) to not more than 8 s (7 s + 1 s).
For the Vickers hardness range and low-force Vickers hardness range tests, the approach speed of the
indenter shall not exceed 0,2 mm/s. For micro-hardness tests, the indenter shall contact the test piece at a
velocity between 0,015 and 0,070 mm/s.
+1
The duration of the test force shall be 14 s , except for tests on materials whose time-dependent properties
−4
would make this an unsuitable range. For these tests, this duration shall be specified as part of the hardness
designation (see EXAMPLE in 4.2).
NOTE 2 It should be noted that for anisotropic materials, for example those w hich have been heavily cold-w orked,
there could be a difference betw een the lengths of the tw o diagonals of the indentation. Therefore, w here possible, the
indentation should be made so that the diagonals are oriented in plane at approximately 45° to the direction of
cold-w orking. The specification for the product may indicate limits for the differences betw een the lengths of the tw o
diagonals.
NOTE 3 There is evidence that some materials may be sensitive to the rate of straining w hich causes changes in the
value of the yield strength. The corresponding effect on the termination of the formation of an indentation can make
alterations in the hardness value.
7.7 Prevention of the effect of shock or vibration
Throughout the test, the testing machine shall be protected from shock or vibration [5].
7.8 Minimum distance between adjacent indentations
The minimum distance between adjacent indentations and the minimum distance between an indentation and
the edge of the test piece are shown in Figure 2.
The distance between the centre of any indentation and the edge of the test piece shall be at least 2,5 times
the mean diagonal length of the indentation in the case of steel, copper and copper alloys, and at least three
times the mean diagonal length of the indentation in the case of light metals, lead and tin and their alloys.
The distance between the centres of two adjacent indentations shall be at least three times the mean diagonal
length of the indentation in the case of steel, copper and copper alloys, and at least six times the mean
diagonal length in the case of light metals, lead and tin and their alloys. If two adjacent indentations differ in
size, the spacing shall be based on the mean diagonal length of the larger indentation.

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Key
1 Edge of test piece
2 steel, copper and copper alloys
3 light metals, lead and tin and their alloys
Figure 2 — Minimum spacing for Vickers indentations
7.9 Measurement of the diagonal length
Measure the lengths of the two diagonals. The arithmetical mean of the two readings shall be taken for the
calculation of the Vickers hardness. For all tests, the perimeter of the indentation shall be clearly defined in the
field of view of the microscope.
Magnifications should be selected so that the diagonal can be enlarged to greater than 25 %, but less than
75 % of the maximum possible optical field of view, see 5.3.
NOTE 1 Many older objective lenses are non-linear tow ards the edge of the field of view . Systems using a camera for
measurement may use 100% of the camera’s field of view provided they are designed to consider the 75 % and any other
field of view limitations of the optical system.
NOTE 2 For indentation diagonals less than 0,020 mm, the increase of the uncertainty has to be considered.
NOTE 3 In general, decreasing the test force increases the scatter of results of the measurements. This is
particularly true for low-force Vickers hardness tests and Vickers microhardness tests, where the principal
limitation will arise in the measurement of the diagonals of the indentation. For Vickers microhardness, the
accuracy of determination of the mean diagonal length is unlikely to be better than  0,001 mm (see
Bibliography [1]-[4]).
NOTE 4 A helpful technique for adjusting optical systems that have Köhler illumination is given in Annex G.
For flat surfaces, the difference between the lengths of the diagonals should not be greater than 5 %. If the
difference is greater, this shall be stated in the test report.
7.10 Calculation of hardness value
Calculate the Vickers hardness value for the tests on flat surfaces using equation given in Table 2. The
Vickers hardness value may also be determined using the calculation table given in ISO 6507-4. For curved
surfaces, the correction factors given in Annex B shall be applied.
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8 Uncertainty of the results
A complete evaluation of the uncertainty should be done according to ISO/IEC Guide 98-3 [6].
Independent of the type of sources, for hardness there are two possibilities for the determination of the
uncertainty.
 One possibility is based on the evaluation of all relevant sources appearing during a direct calibration. As

a reference, a Euramet guideline [7] is available.
 The other possibility is based on indirect calibration using a hardness reference block [below abbreviated
as CRM (certified reference material)] (see [7-10] in the Bibliography). A guideline for the determination is
given in Annex D.
It may not always be possible to quantify all the identified contributions to the uncertainty. In this case, an
estimate of type A standard uncertainty may be obtained from the statistical analysis of repeated indentations
into the test piece. Care should be taken, if standard uncertainties of type A and B are summarised, that the
contributions are not counted twice (see Clause 4 of GUM [6]).
9 Test report
The test report shall include the following information unless otherwise agreed by the parties concerned:
a) a reference to this part of ISO 6507;
b) all details necessary for identification of the test piece;
c) the date of the test;
d) the hardness result obtained in HV, reported in the format defined in 4.2;
e) all operations not specified in this part of ISO 6507, or regarded as optional;
f) details of any occurrence which may have affected the results;
g) the temperature of the test, if it is outside the ambient range specified in 7.1;
h) where conversion to another hardness scale is also performed, the basis and method of this conversion
shall be specified.
NOTE 1 There is no general process of accurately converting Vickers hardness into other scales of hardness or into
tensile strength. Such conversions, therefore, should be avoided, unless a reliable basis for conversion can be obtained by
comparison tests (see also ISO 18265 [12]).
NOTE 2 A strict comparison of hardness values is only possible at identical test forces.
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Annex A
(normative)

Minimum thickness of the test piece in relation to the test force and to
the hardness

Key
X Thickness of the test piece, mm
Y Hardness, HV
Figure A.1 — Minimum thickness of the test piece in relation to the test force and to the hardness
(HV 0,2 to HV 100)


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Key
a
Hardness value, HV
b
Minimum thickness, t, mm
c
Diagonal length, d, mm
d
Hardness symbol, HV
e
Test force F, N
Figure A.2 — Nomogram designed for the minimum thickness of the test piece (HV 0,01 to HV 100)
The nomogram shown in Figure A.2 has been designed for the minimum thickness of a test piece, assuming
that the minimum thickness has to be 1,5 times the diagonal length of the indentation. The required thickness
is given by the point of intersection of the minimum thickness scale and a line (shown dotted in the example in
Figure A.2) joining the test force (right-hand scale) with the hardness (left-hand scale).
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Annex B
(normative)

Tables of correction factors for use in tests made on curved surfaces
B.1 Spherical surfaces
Tables B.1 and B.2 give the correction factors when tests are made on spherical surfaces.
The correction factors are tabulated in terms of the ratio of the mean diagonal d of the indentation to the
diameter D of the sphere.
EXAMPLE Convex sphere, D  10 mm
Test force, F = 98,07 N
Mean diagonal of indentation, d  0,150 mm
d 0,150

 0,015
D 10
98,07
Vickers hardness 0,189 1 824 HV 10

2
(0,15)
Correction factor from Tab
...