SIST EN 623-5:2009

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.WUXNWXUHHochleistungskeramik - Monolithische Keramik - Allgemeine und strukurelle Eigenschaften - Teil 5: Bestimmung des Volumenanteils von Phasen durch Auswertung von MikrogefügeaufnahmenCéramiques techniques avancées - Céramiques monolithiques - Propriétés générales et textures - Partie 5: Détermination de la fraction volumique de phase par évaluation des microphotographiesAdvanced technical ceramics - Monolithic ceramics - General and textural properties - Part 5: Determination of phase volume fraction by evaluation of micrographs81.060.30Sodobna keramikaAdvanced ceramicsICS:Ta slovenski standard je istoveten z:prEN 623-5kSIST prEN 623-5:2009en,fr,de01-marec-2009kSIST prEN 623-5:2009SLOVENSKI
STANDARD



kSIST prEN 623-5:2009



EUROPEAN STANDARDNORME EUROPÉENNEEUROPÄISCHE NORMFINAL DRAFTprEN 623-5December 2008ICS 81.060.30Will supersede ENV 623-5:2002
English VersionAdvanced technical ceramics - Monolithic ceramics - Generaland textural properties - Part 5: Determination of phase volumefraction by evaluation of micrographsCéramiques techniques avancées - Céramiquesmonolithiques - Propriétés générales et textures - Partie 5:Détermination de la fraction volumique de phase parévaluation des microphotographiesHochleistungskeramik - Monolithische Keramik -Allgemeine und strukurelle Eigenschaften - Teil 5:Bestimmung des Volumenanteils von Phasen durchAuswertung von MikrogefügeaufnahmenThis draft European Standard is submitted to CEN members for unique acceptance procedure. It has been drawn up by the TechnicalCommittee CEN/TC 184.If this draft becomes a European Standard, CEN members are bound to comply with the CEN/CENELEC Internal Regulations whichstipulate the conditions for giving this European Standard the status of a national standard without any alteration.This draft European Standard was established by CEN in three official versions (English, French, German). A version in any other languagemade by translation under the responsibility of a CEN member into its own language and notified to the CEN Management Centre has thesame status as the official versions.CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Cyprus, Czech Republic, Denmark, Estonia, Finland,France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal,Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland and United Kingdom.Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without notice andshall not be referred to as a European Standard.EUROPEAN COMMITTEE FOR STANDARDIZATIONCOMITÉ EUROPÉEN DE NORMALISATIONEUROPÄISCHES KOMITEE FÜR NORMUNGManagement Centre:
Avenue Marnix 17,
B-1000 Brussels© 2008 CENAll rights of exploitation in any form and by any means reservedworldwide for CEN national Members.Ref. No. prEN 623-5:2008: EkSIST prEN 623-5:2009



prEN 623-5:2008 (E) 2 Contents page Foreword.3 1 Scope.4 2 Normative references.4 3 Terms and definitions.5 4 Apparatus.5 4.1 Sectioning equipment.5 4.2 Mounting equipment.5 4.3 Grinding and polishing equipment.5 4.4 Microscope.5 4.5 Transparent grid.5 5 Test piece preparation.6 5.1 Sampling.6 5.2 Cutting.6 5.3 Mounting.6 5.4 Grinding and polishing.6 5.5 Etching.6 6 Photomicrography.7 6.1 General aspects.7 6.2 Inspection.7 6.3 Number of micrographs.7 6.4 Optical microscopy.7 6.5 Scanning electron microscopy (SEM).7 7 Measurement of micrographs.8 8 Calculation of results.8 9 Interferences and uncertainties.9 10 Test report.9 Annex A (informative)
Grinding and polishing procedures.11 Annex B (informative)
Etching procedures.13 Annex C (informative)
Use of automatic image analysis (AIA).15 C.1 Background.15 C.2 Analysis techniques.15 C.3 Micrograph requirements.15 C.4 Calibration.15 Annex D (informative)
Setting Köhler illumination in an optical microscope.16 D.1 Purpose.16 D.2 Definition.16 D.3 Setting up for Köhler illumination.16 Annex E (informative)
Round robin verification of this procedure.17 Annex F (informative)
Results sheet.18 Bibliography.19
kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 3 Foreword This document (prEN 623-5:2008) has been prepared by Technical Committee CEN/TC 184 “Advanced technical ceramics”, the secretariat of which is held by BSI. This document is currently submitted to the Unique Acceptance Procedure. This document will supersede ENV 623-5:2002. EN 623 consists of five parts, under the general title "Advanced technical ceramics - Monolithic ceramics - General and textural properties": Part 1: Determination of the presence of defects by dye penetration Part 2: Determination of density and porosity Part 3: Determination of grain size and size distribution (characterized by the Linear Intercept Method) Part 4: Determination of surface roughness Part 5: Determination of phase volume fraction by evaluation of micrographs
kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 4
1 Scope This part of EN 623 specifies a manual method of making measurements for the determination of volume fraction of major phases in advanced technical ceramics using micrographs of polished and etched sections, overlaying a square grid of lines, and counting the number of intersections lying over each phase. NOTE 1 This method assumes that the true phase volume fractions are equivalent to area fractions on a randomly cut cross-section according to stereological principles. NOTE 2 Guidelines for polishing and etching of advanced technical ceramics can be found in Annexes A and B. The method applies to ceramics with one or more distinct secondary phases, such as found in Al2O3/ZrO2, Si/SiC,or Al2O3/SiCw. If the test material contains discrete pores, these can be treated as a secondary phase for the purpose of this method provided that there is no evidence of grain pluck-out during polishing being confused with genuine pores. NOTE 3 If the material contains more than about 20 % porosity there is a strong risk that the microstructure will be damaged during the polishing process, and measurement of volume fraction of pores may become misleading. Secondary phase volume fractions or porosity present at levels of less than 0,05 are subject to considerable error and potential scatter in results. A larger number of micrographs than the minimum of three is normally needed to improve the consistency and accuracy of the results. NOTE 4 Many ceramics contain small amounts of secondary glassy phases. In order to make a reasonable estimate of glassy phase content, the glass material between crystalline grains should be readily observable, and thus should be at least 0,5 µm in width. The method in this European Standard is not considered appropriate for narrow glassy films around grains. This method assumes that the selected regions of a prepared cross-section are statistically representative of the whole sampled section. NOTE 5 Microstructures are seldom homogeneous, and the phase contents can vary from micrograph to micrograph. It is essential to survey a sufficiently wide area of the prepared section to ensure that those areas selected for evaluation are representative, and do not contain eye-catching irregularities. Some users of this European Standard can wish to apply automatic or semiautomatic image analysis to micrographs or directly captured microstructural images. This is currently outside the scope of this European Standard, but some guidelines are given in Annex C. 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. prEN 1006, Advanced technical ceramics - Monolithic ceramics - Guidance on the selection of test pieces for the evaluation of properties EN ISO/IEC 17025, General requirements for the competence of testing and calibration laboratories (ISO/IEC 17025:2005) kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 5 3 Terms and definitions For the purposes of this part of EN 623, the following terms and definitions apply. 3.1 phase volume fraction volume occupied by a distinct, identifiable phase present in a material expressed as a fraction of the whole 3.2 secondary phase one or more distinct identifiable phases other than a primary crystalline phase in a material NOTE A secondary phase can be in the form of discrete grains, or as a continuous phase surrounding some or all the major phase grains. For the purposes of this European Standard, porosity may be treated as a secondary phase. 4 Apparatus 4.1 Sectioning equipment A suitable diamond-bladed cut-off saw to prepare the initial section for investigation. The saw shall be metal bonded with a diamond grit size of 125 µm to 150 µm and shall be cooled. NOTE This grit size is designated D151 according to ISO 6106, see [1]. 4.2 Mounting equipment Suitable metallurgical mounting equipment and media for providing firm gripping of the test piece for polishing. 4.3 Grinding and polishing equipment Suitable grinding and polishing equipment, employing diamond abrasive media. NOTE A sequence of abrasives and techniques recommended for polishing are given in Annex A. 4.4 Microscope An optical or scanning electron microscope with photomicrographic facilities. NOTE Although the true magnification of the image is unimportant for making the measurement of volume fraction, it is advised that a reference graticule may be used to determine magnification in an optical microscope, or a reference grid or latex spheres may be used for calibration of magnification in a scanning electron microscope, and as a check on the homogeneity of magnification across the field of view. An optical microscope is additionally required for assessing polishing (see 5.4). 4.5 Transparent grid Transparent square grid on, e.g. acetate film, and with line thickness not exceeding 0,1 mm. NOTE 1 The grid spacing selected is not critical, but may conveniently be between 3 mm and 15 mm to minimise eyestrain. However, it is necessary that consideration of the requirements of 6.3 is taken into account. NOTE 2 A suitable grid may be prepared as a computer plot with sufficient accuracy of line spacing for the purposes of this European Standard.
kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 6 5 Test piece preparation 5.1 Sampling The test pieces shall be sampled in accordance with the guidelines given in prEN 1006, and subject to agreement between parties. NOTE Depending on the objectives of performing the measurement, it is desirable to maintain knowledge of the positions within components or test pieces from which sections are prepared. 5.2 Cutting The required section of test-piece shall be cut using the diamond saw (see 4.1). NOTE For routine inspection of materials, a small area of side no more than 10 mm is normally adequate as the section to be polished. 5.3 Mounting Mount the test piece using an appropriate mounting medium. If the ceramic is suspected to have significant open porosity in some regions (see Clause 1) it is advisable to vacuum impregnate the test piece with liquid mounting resin before encapsulating as this will provide some support during grinding and polishing. NOTE It is not essential to encapsulate the test piece. For example, it could be affixed to a metal holder. However, encapsulation in a polymer-based medium allows easy gripping and handling, especially of small irregularly shaped test pieces and of weak friable test pieces. The method of mounting selected should take into account the etching procedure to be used; see Annex B. 5.4 Grinding and polishing Grind and polish the surface of the test piece. Care should be taken to ensure that grinding produces a planar surface with a minimum of damage. Employ successively smaller grit sizes, at each stage removing the damage from the previous stage until there is no change in appearance when examined by an optical microscope (see 4.4) at high magnification. At least 90 % of the test piece area shall be free from optically visible scratches, or other damage introduced by polishing, which will interfere with the determination. In particular, discrete secondary phases may be plucked out from the surface giving the appearance of pores. This shall be avoided. NOTE Care should be taken in choosing the sequence of grits and lap types. It is impossible within the scope of this part of EN 623 to make specific recommendations for all types of material. The general principle to be adopted is the minimisation of subsurface damage, and its removal by progressively finer grits whilst retaining a flat surface. Some guidelines on polishing are given in Annex A. 5.5 Etching When a good quality polished surface has been achieved, the test piece shall be etched if necessary to reveal the individual phases. Any suitable technique shall be used, subject to agreement between parties. NOTE 1 Some general guidelines recommending etching procedures for various commonly available advanced technical ceramics are given in Annex B. NOTE 2 For optical evaluation, it is usually necessary to etch oxide materials in such a way that the individual phases are distinguished by having different contrast levels. For evaluation by scanning electron microscopy (SEM), it may not be necessary to etch if a backscattered electron detector is used which has adequate resolution of net atomic number difference between the phases such that contrast is generated. If a secondary electron detector is used, it will usually be necessary to etch to produce topographic contrast unless the atomic number difference between the phases is large. kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 7 6 Photomicrography 6.1 General aspects If it suspected that the average grain size of each phase or the widths of continuous glassy phases between grains is less than 2 µm, it will be necessary to prepare the test piece for SEM. Between 2 µm and 4 µm either SEM or optical microscopy may be used. Otherwise, optical microscopy will normally be adequate. It is important to achieve sufficient contrast between phases in order to identify individual grains clearly and unambiguously. 6.2 Inspection Inspect the sampled cross-section in the microscope. If the microstructure appears homogeneous, prepare micrographs from randomly selected areas. If inhomogeneity of microstructure is suspected, select representative areas of relevance for measurement. 6.3 Number of micrographs At least three micrographs shall be prepared at a magnification sufficient to identify clearly all the phases to be counted. In addition, at least 100 features in total of any given type shall be present to be counted in the set of micrographs. NOTE For a nominally homogeneous material, it may be sufficient to use a small number of micrographs analysed with a small grid spacing, but for an inhomogeneous material, results representative of the average for the sampled section can be prepared reliably only by selecting a large number of micrographs of different areas, with less intensive counting from a larger grid. 6.4 Optical microscopy Set up Köhler illumination in the microscope. NOTE Guidance on setting Köhler illumination conditions is given in Annex D. Examine the test piece at a magnification sufficient to resolve the individual grains clearly. If the contrast obtained is insufficient, e.g. in white or translucent materials, apply a suitable thin metallic coating by evaporation or sputtering. Prepare micrographs of at least three different randomly selected areas of the test-piece surface, taking into account the apparent homogeneity of the microstructure (see 6.2). As a guideline, the average size of discrete phase area to be counted should appear typically at least 3 mm across. If the total number of individual grains of any one phase to be counted in any one set of micrographs is less than one hundred, prepare more micrographs. Micrographs should be typically of a size (100 x 75) mm, but may with advantage be enlarged later to aid evaluation. 6.5 Scanning electron microscopy (SEM) Mount the test piece on the test piece holder of the microscope. If the test piece is not electrically conducting, apply a thin evaporated or sputtered conductive coating. Insert the test-piece in the microscope, ensuring that the surface to be characterised is normal to the electron beam to within 5°. NOTE 1 This ensures that the image does not suffer from excessive distortion or loss of focus due to the angle of viewing. Prepare micrographs at a suitable magnification (see 6.4) from at least three different randomly selected areas of the test piece, using either secondary electron imaging or backscattered electron imaging. NOTE 2 Although the contrast between phases can be enhanced using backscattered electron imaging, a noisier image than in secondary electron imaging may result and may render the boundaries between contrasting phases indistinct. It can be helpful to use secondary electron images for counting the phase proportions, but backscattered images to aid identification of each phase. kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 8 If the number of grains of the phase to be counted is less than 100 in total over all the micrographs, increase the number of areas photographed. Micrographs should typically be of a size (100 x 75) mm, but may with advantage be enlarged later to aid evaluation. NOTE 3 It is possible that the photographic screen in the microscope will not have constant magnification at all points. A square grid makes a suitable reference for ascertaining the degree of distortion in the screen, since it is easy to detect distortions of the grid. For the purposes of this test method, distortions of typically up to 5 % may be acceptable provided that the phases being counted are distributed homogeneously across the entire area of the micrograph. 7 Measurement of micrographs If desirable, enlarge the photomicrograph to a size suitable for easier observation of the features. Examine the dimensions of the smallest features to be counted. Select a suitable grid spacing and prepare a square grid (see 4.5, 6.3 and comments in Clause 9) such that the grid area covers the entire micrograph. Tape the micrograph to a smooth surface. Overlay the grid such that the entire area of the micrograph is covered by the grid, with no grid intersections immediately over the edges of the micrograph. Count the number of grid intersections nj of the grid that lie over each phase j. If the grid intersection lies exactly over the boundary between two phases, count this as one half of a grid intersection for each phase. If porosity is to be estimated, use the same rule for when a grid intersection lies exactly on the edge of a pore. Count the total number of grid intersections over the area of the micrograph. If pores are not being counted, count the number of grid intersections lying over the crystalline or glassy phases in the material. NOTE It can be helpful in counting to screen with pieces of paper those lines of intersections above and below the one being counted; this reduces eye strain and the risk of miscounting. 8 Calculation of results For the case where porosity is to be counted as one of the phases, calculate the volume fraction of each phase using Equation (1): where
n j is the total number of grid intersections over phase j;
N is the total number of grid intersections lying over the micrograph.
For the case where porosity is to be ignored, see Equation (2): where
n j is the number of grid intersections lying over solid phase j;
Nn
=
Vj ij f (1)
)n-
(Nn
=
n n
=
Vpj ij ij ij fΣ (2) kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 9
np is the number of grid intersections lying over pores;
S is the sum of all grid intersections lying over all solid phases. 9 Interferences and uncertainties The nature of the microstructure of the material can affect the result determined in this test. The test is effective when a sufficient number of grid intersections of each phase are counted. This can be achieved either by intensive analysis of the minimum number of three micrographs, or by less intensive analysis of a larger number of micrographs. For intensive analysis, the grid shall be small enough such that there is a good chance that a grid intersection will lie over each grain. Failure to do this means that the results are subject to increasing possible random error depending on exactly where the grid is positioned. The random error is minimised by adhering to the above guideline, but will always exist because of random positioning of the grid on the micrograph. Typically, for a homogeneous material with randomly distributed phases results from a given series of three micrographs counting at least 100 grains of each type should give phase volume fractions consistent to ± 0,02. If the material appears inhomogeneous, either more areas should be analysed intensively to establish the extent of the inhomogeneity, or if an average result only is required, a larger grid spacing can be used for less intensive analysis provided that at least 100 grains of each phase type in total are counted. The procedure adopted should be reported. The counting process requires visual observation of the phase lying underneath each grid intersection. Clean, well-defined phase boundaries are required. If the phase boundaries are poorly defined as a result of limited optical or SEM resolution, it is necessary to adopt a consistent criterion for assessing which side of the true boundary the grid intersection overlies. Failure to do this can lead to under or overestimation of phase volume fraction, and is particularly dangerous for small volume fractions. The micrographs should not contain features which are ambiguous. Grain pluckout during polishing could inadvertently be treated as porosity and, vice versa, features seen within shallow pores might be counted as solid grains. Particular caution should be taken to avoid subsurface grains giving strong signals in backscattered electron images, or edge highlights in secondary electron images hiding individual grains. NOTE Annex E contains information from a round robin activity associated with the development of this European Standard which illustrates these concerns. 10 Test report The report of the test shall be in accordance with the reporting provisions of EN ISO/IEC 17025 and shall include at least the following information: a) name and address of the testing establishment; b) date of the test; c) on each page, a unique report identification and page number; d) customer name and address; e) reference to this European Standard, i.e. determined in accordance with EN 623-5; f) authorizing signature; NOTE 1 For routine presentation of results it is useful if a standardised format is adopted. A recommended scheme is given in Annex F. g) any deviation from the method described, with appropriate validation, i.e. demonstrated to be acceptable to the parties involved; h) details of the test piece, including material type, manufacturing code, batch number, etc.; kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 10 i) observation technique employed (optical or scanning electron microscope); j) a summary of the procedure for sampling, cutting, grinding, polishing and etching the test piece; k) copies of the micrographs used for the measurements; NOTE 2 It is good practice to provide magnifications on all micrographs, even though not a requirement of this European Standard. l) grid size employed; m) number of grid intersections lying over each of the defined phases, including pores if appropriate, on each of the micrographs; n) total number of grid intersections on each micrograph; o) calculated volume fractions of each phase in each micrograph, and the overall result from all micrographs, expressed as a decimal number to two significant figures; p) any remarks on the appearance of the microstructure, and difficulties of observing the individual phases. kSIST prEN 623-5:2009



prEN 623-5:2008 (E) 11 Annex A
(informative)
Grinding and polishing procedures Preparation of polished sections of ceramics requires different procedures from those conventionally employed for metallic materials, which typically commence with a coarse grinding stage using fixed grit silicon carbide papers of grit sizes of 30 µm or greater (see [1] for information on grit size coding). For ceramic materials, this type of procedure can produce considerable amounts of sub-surface damage in the form of extended microcracks which can then influence the microstructural appearance obtained, unless precautions are taken to minimise such damage and to
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