Post on 21-May-2018
transcript
Exp.3: Preparation of Specimens for
Metallographic Examination
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ENG. MOHAMMED ABU ELKHAER
ENG.HASAN ZAIDAH
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Objective of the experiment
To learn and to gain experience in the preparation of metallographic specimens.
To prepare the specimens surfaces to be examined for their microstructure study by the
microscope .
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.
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Introduction …cont.
Such microscopic studies can provide constitutional information
about the specimen under investigation, including:
• The size and shape of the grains,
• The presence of micro defects.
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Introduction …cont.
Proper preparation of metallographic specimens to determine
microstructure and content requires that a rigid step-by-step
process be followed. In sequence, the steps include:
• Sectioning (cutting),
• Mounting,
• Grinding,
• Polishing,
• Etching ,
• Microscopic examination.October 11,
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Sectioning (cutting)
The preparation starts by cutting a small representative piece of the
metal to be studied.
Cutting can change the microstructure of a sample.
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Sectioning (cutting)
Minitom: Small, automatic precision cut-off machine for
sectioning all materialographic and ceramic specimens.
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Cleaning
Specimens must be kept clean in order to reveal accurate
microstructures.
Metason: Ultrasonic Cleaning.
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Cleaning
The process is carried out using an ultrasonic cleaning machine.
The process removes dirties and loose particles.
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Mounting
The process of coating the sample.
Mounting of specimens is usually necessary to:
• Allow them to be handled easily.
• Minimizes the amount of damage likely to be caused to the
specimen itself.
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Mounting
LaboPress-3: Semi-automatic mounting press for hot mounting of all
materials.
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Mounting
In hot-mounting the sample is surrounded by an organic polymeric
powder which melts under the influence of heat (about 200 𝑂𝐶).
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Mounting
It is important to supply enough resin during mounting. If the
amount of resin is too small to cover the specimen after curing, the
specimen, the ram and the cylinder may all be damaged.
Min. no. of Spoons =
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Grinding
Surface layers damaged by cutting must be removed by grinding.
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Grinding
LaboPol (grinding and polishing machine): Machines for
grinding, lapping and polishing for 200 or 230 mm discs.
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MD-Largo MD-Primo
Grinding
LaboForce: Specimen movers for semi-automatic
preparation of materialographic specimens on LaboPol
grinding and polishing machines.
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Grinding
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Polishing
To remove deformations from grinding and obtain a surface that is
highly reflective.
Polishing discs are covered with soft cloth.
MD-ClothsOctober 11,
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Polishing
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Etching
Etching occurs when the acid or base is placed on the specimen
surface. The purpose of etching:
• Grinding and polishing operations produce a highly deformed,
thin layer on the surface which is removed chemically during
etching.
• Etching is used to reveal the microstructure of the metal
through selective chemical attack.October 11,
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Etching
LectroPol-5: Automatic, microprocessor controlled
electrolytic polishing and etching of metallographic
specimens.
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Grinding
Polishing Etching
More Etching
Procedure
n100 = Nm * [M / 100]2
n100 : number of grains per square inch at 100x magnification.
Nm : number of grains per square inch at the magnification M of the
photomicrograph.
N100= 2N-1
The ASTM grain size number N= [ ln (N100 ) / ln ( 2) ] + 1
How to calculate the are of one grain (actual area of grain at M1)?
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How to calculate the grain size
Let M =200
A = 2*3 = 6 inch2
nm = 200 grain /6 inch2 = 33.3 grain / inch2
n100 = nm * [M / 100]2
=33.3*[200/100]2
n100 =133.2 grain / inch2
N= [ ln ( n ) / ln ( 2) ] + 1
= [ ln ( 133.2) / ln ( 2) ] + 1
= 8.06 grain / inch2
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