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Exp.5: Preparation of Specimens for Metallographic Examination

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Title: Exp.5: Preparation of Specimens for Metallographic Examination Author: Reem Last modified by: Sheikholeslam-Nouri, Ali Created Date: 8/16/2006 12:00:00 AM – PowerPoint PPT presentation

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Title: Exp.5: Preparation of Specimens for Metallographic Examination


1
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2
Preparation of Specimens for Metallographic
Examination

3
Metallography
4
INDEX
  • Objectives
  • Introduction
  • Metallography
  • Questions

5
Objective
  • To prepare the specimens surfaces to be examined
    for their microstructure study by the microscope
    .
  • To learn and to gain experience in the
    preparation of metallographic specimens.

6
Introduction
  • Metallography is basically the study of the
    structures and constitution of metals and alloys,
    using metallurgical microscopes and
    magnifications, so that the physical and
    mechanical properties of an alloy can be related
    to its observed microstructure.
  • It provides information about the specimen under
    investigation, including the size and shape of
    the grains (crystallites), the presence of micro
    defects (such as segregation, hair cracks, and
    nonmetallic inclusions), and the nature and
    distribution of secondary phases.

7
Metallography
  • Cutting
  • Grounding emery paper (240, 300, 400, 600)
  • Polishing (0.5, 0.1, 0.05µ)
  • Etching Nitol/ Kellers Solution
  • Microscopy

8
Grounding
  • grinding is a subset of cutting, as grinding is a
    true metal cutting process.
  • Abrasive The use of Premium SiC abrasive paper
    is the most efficient and practical technique for
    grinding metallic metallographic specimens.
    Although many qualities of silicon carbide are
    readily available, only the premium grade SiC
    powder provides the most consistent results and
    highest grinding rates.
  • Each grain of abrasive functions as a microscopic
    single-point cutting edge and shears a tiny chip
    that is analogous to what would conventionally be
    called a "cut" chip (turning, milling, drilling,
    tapping, etc.)

9
Grinding Soft non-ferrous metals
  • Soft non-ferrous metals - Initial grinding is
    recommended with 320 grit SiC
  • abrasive paper followed by 320 400, 600 and ,
    800 grit SiC paper. because These materials are
    relatively soft they do not easily break down the
    SiC paper.
  • The initial grinding with 320 grit is generally
    sufficient for minimizing initial deformation
    and yet maintaining adequate removal rates.
  • For extremely soft materials such as tin, lead
    and zinc it is also recommended that the abrasive
    paper be lightly coated with a paraffin wax. The
    wax reduces
  • the tendency of the SiC abrasive to embed into
    the soft specimen.

10
Grinding Ferrous metals
  • Ferrous metals - are relatively easy to grind
    with the depth of deformation being a major
    consideration.
  • 120 grit SiC abrasives provide a good
    initial start with subsequent use of 240 or 320,
    400, 600 and 800 grit SiC.
  • Super alloys - are generally of moderate hardness
    but have extremely stable elevated temperature
    characteristics and corrosion resistance.
  • the procedures for preparing super alloys is very
    similar to that for most non-ferrous metals.

11
  • Sample Preparation
  • The purpose of this practice is to understand how
    to prepare and interpret metallographic samples
    systematically.
  • Gather information about chemical composition,
    heat treatment, processing, phase diagram.
  • Cut representative sample.
  • Mount sample, grind and polish.
  • Examine un etched sample.
  • Etch lightly and examine again.
  • Etch further if necessary.
  • Compare with microstructure expected from
    equilibrium phase diagram

12
Spheroidal Graphite Cast Iron

13
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14
Abrasive Material
  • Materials used for the abrading particles are
  • garnet commonly used in woodworking
  • emery commonly used to abrade or polish metal
  • aluminium oxide perhaps most common in widest
    variety of grits can be used on metal (i.e. body
    shops) or wood
  • silicon carbide available in very coarse grits
    all the way through to micro-grits, common in wet
    applications
  • alumina-zirconia (an aluminium oxidezirconium
    oxide alloy), used for machine grinding
    applications
  • chromium oxide used in extremely fine micron
    grit (micrometre level) papers
  • ceramic aluminum oxide used in high pressure
    applications, used in both coated abrasives, as
    well as in bonded abrasives.

15
Polishing
  • Polishing is the process of creating a smooth and
    shiny surface by rubbing it or using a chemical
    action, leaving a surface with a significant
    reflection
  • Aluminum Oxide(0.5, 0.1, 0.05µ)

16
PROCESS
  • The specimen must1. Be free from scratches,
    stains and others imperfections which
  • tend to mark the surface.
  • 2. Reveal no evidence of chipping due to brittle
    inter metallic
  • compounds and phases.
  • 3. Be free from all traces of disturbed metal.
  • 4. The specimen has to be grounded with the help
    of abrasive papers.
  • 5. Polishing enhances the surface and makes it
    suitable to observe its
  • grain structure under Microscope.

17
Grain
  • The micro structure of many metallic or ceramic
    materials consists of many grains.
  • A grain
  • is portion of the materials within which the
    arrangement of the atoms is nearly identical but
    the orientation or crystal structure of atoms
  • are different.

18
A Grain Boundary
  • The surface that separates the individual grains
    is a narrow zoon in which the atoms are properly
    spaced.
  • One method of controlling the properties of a
    material is by controlling the grain size.

19
Surface Defects
  • Surface defects are the boundaries, or plans,
    that separate a material into regions.
  • Each region may have the same crystal structure
    but different orientation

20
Industrial etching
  • The surface is than exposed to chemical attack
    or ETCHING, with grain boundaries being attacked
    more aggressively than reminder of the grain to
    reveal the microstructure.
  • Light from an optical microscope is reflected or
    scattered from the sample surface depending how
    the surface is etched

21
Etching
Sample material Etchant Composition Remarks
Carbon steel (usually 2) (nitric acid) HNO3 1-5 ml Ethyl alcohol 100ml Few seconds (15 Sec)
Carbon steel Picric Acid Picric acid 4g Ethyl alcohol 100ml Few seconds (15 Sec)
Aluminum Hydrofluoric acid HF (conc.) 0.5ml H2O 99.5ml Swab for 15 sec.
22
Surface Finish and Surface Roughness
(Original Magnification 50x)
23
REFERENCES
  • http//sembach.com/uploads/images/brevier/bild18.g
    if
  • http//www.springerimages.com/img/Images/Springer/
    JOU11661/VOL2011.42/ISU9/ART688/MediaObjects/M
    EDIUM_11661_2011_688_Fig26_HTML.jpg
  • http//www.springerimages.com/img/Images/Springer/
    JOU11661/VOL2011.42/ISU11/ART749/MediaObjects/
    MEDIUM_11661_2011_749_Fig1_HTML.jpg
  • http//www.sfsa.org/tutorials/uplock/images/Grains
    .Jpg
  • http//ars.els-cdn.com/content/image/1-s2.0-S00431
    64804002364-gr11.jpg
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