INTRODUCTION
Mechanical engineers are primarily
interested in the mechanical behavior of metals because they have to consider
about the quality of material before it use for a final product. The final
product is used by the customer, therefore they have to make sure that there
are no any defects and final product is in the exact quality.
There are four types of defects.
They are,
1. Point
defects
2. Line
defects
3. Planner
defects
4. Bulk
defects
Within
this experiment we were expected to examine the bulk defects affected in given
some samples which has been undergone,
v Ductile
failure
v Brittle
failure
v Fatigue
failure
v Creep
Failure
Ductile failure
Metal
that deform plastically under the tension are called ductile materials, plastic
deformation take place by ‘slip’ of atoms on the planes that are of densest
atomic packing and along the direction of highest linear density therefore
practically in f.c.c metals which are of high ductility plastic deformation,
and then final facture of a cup and cone type occurs.
Brittle failure
Brittle
fracture is a rapid run of cracks through a stressed material. The cracks
usually travel so fast that you can't tell when the material is about to break.
In other words, there is very little plastic deformation before failure occurs.
In most cases, this is the worst type of fracture because you can't repair
visible damage in a part or structure before it breaks. In brittle fracture,
the cracks run close to perpendicular to the applied stress.
Fatigue failure
Fatigue
is the fracture that occurs in components that are subjected to replaced
(cyclic/alternating) loads.
σ max= maximum stress
σ min= minimum stress
Fatigue failure occurs in three stages,
1. Crack initiation - A crack has to initiate on the surface of a
component, for it to fail by fatigue
generally a crack initiates at a point of high stress concentration
2. Crack propagation - When the crack reaches a critical crack length,
the crack will be propagating continuously at each
maximum stress cycle.
3. Final failure - When the remaining section cannot withstand the load
applied brittle type of fracture
occurs
Creep failure
Creep occurs at temperature well above room
temperature under constant load. This deformation is plastic and occurs at
stresses even below the yield stress of
the material. The temperature at which materials start to creep depends
on their melting point.
In
this experiment we use some tests to examine the bulk defects. They are,
1.
Macro-structure
Examination
Macro- (Macrography, Macrostructure)
Examination is a method of examination of large regions of the
specimen surface or fractured section with the naked eye or under low
magnification. The following macrostructure details may be studied:
·
Macro-segregation
of the alloying elements or impurities (sulfur in steel, antimony in lead base Babbitt)
·
Large non-metallic inclusions
such oxides, sulphides or slag
2. Fracture Examination
This is a method relating to
observation of the broken surfaces of the failed part. The appearance of the
surfaces may be a result of brittle fracture, fatigue
with its characteristic fracture, intercrystalline fracture, segregation, slag
particles, cracks, starting from physical defects, rough surface, corrosion and other causes. Fracture
examination should take into account the working condition, the history of the
part, possible overloads, applied to the part, misalignments and other working
factors.
3.
Non-
Destructive Testing
As the term ‘Non- Destructive’ implies there is no impairment of the
properties of the article consequent to testing. There is variety of
non-destructive tests. Most important methods are,
1. Liquid
Penetrant Testing
Liquid
penetrant inspection, also called Dye penetrant inspection, is a widely applied and low-cost
inspection method used to locate surface-breaking defects in all non-porous
materials (metals, plastics, or ceramics). Penetrant may be applied to all
non-ferrous materials, but for
inspection of ferrous components magnetic-particle inspection is preferred for its subsurface detection
capability. LPI is used to detect casting and forging defects, cracks,
and leaks in new products, and fatigue cracks on in-service components.
Below are the main steps of Liquid Penetrant
Inspection:
·
Pre-cleaning:
The
test surface is cleaned to remove any dirt, paint, oil, grease or any loose
scale that could either keep penetrant out of a defect, or cause irrelevant or
false indications. Cleaning methods may include solvents, alkaline cleaning
steps, vapor degreasing, or media blasting. The end
goal of this step is a clean surface where any defects present are open to the
surface, dry, and free of contamination.
·
Application
of Penetrant:
The penetrant is then applied to
the surface of the item being tested. The penetrant is allowed time to soak
into any flaws (generally 10 to 30 minutes). The soak time mainly depends upon
the material being testing and the size of flaws sought. As expected, smaller
flaws require a longer penetration time. Due to their incompatible nature one
must be careful not to apply visible red dye penetrant to a sample that may
later be inspected with fluorescent penetrant.
·
Excess
Penetrant Removal:
The
excess penetrant is then removed from the surface. Removal method is controlled
by the type of penetrant used. Water-washable, solvent-removable, lipophilic
post-emulsifiable, or hydrophilic post-emulsifiable are the common choices.
Emulsifiers represent the highest sensitivity level, and chemically interact
with the oily penetrant to make it removable with a water spray. When using
solvent remover and lint-free cloth it is important to not spray the solvent on
the test surface directly, because this cans the remove the penetrant from the
flaws. This process must be performed under controlled conditions so that all
penetrant on the surface is removed (background noise), but penetrant trapped
in real defects remains in place.
·
Application
of Developer:
After
excess penetrant has been removed a white developer is applied to the sample.
Several developer types are available, including: non-aqueous wet developer,
dry powder, water suspendible, and water soluble. Choice of developer is
governed by penetrant compatibility (one can't use water-soluble or suspedible
developer with water-washable penetrant), and by inspection conditions. When
using non-aqueous wet developer (NAWD) or dry powder the sample must be dried
prior to application, while soluble and suspendible developers are applied with
the part still wet from the previous step. NAWD is commercially available in
aerosol spray cans, and may employ acetone,
isopropyl alcohol, or a propellant that is a
combination of the two. Developer should form a thin, even coating on the
surface.
The developer draws penetrant
from defects out onto the surface to form a visible indication, a process
similar to the action of blotting paper. Any colored stains indicate the
positions and types of defects on the surface under inspection.
·
Inspection:
The
inspector will use visible light with adequate intensity (100 foot-candles is
typical) for visible dye penetrant. Ultraviolet (UV-A) radiation of adequate
intensity (1,000 micro-watts per centimeter squared is common), along with low
ambient light levels (less than 2 foot-candles) for fluorescent penetrant
examinations. Inspection of the test surface should take place after a 10
minute development time. This time delay allows the blotting action to occur.
The inspector may observe the sample for indication formation when using
visible dye, but this should not be done when using fluorescent penetrant. Also
of concern, if one waits too long after development the indications may
"bleed out" such that interpretation is hindered.
·
Post
Cleaning:
The
test surface is often cleaned after inspection and recording of defects,
especially if post-inspection coating processes are scheduled.
2. Eddy
Current Testing
In this method
we use electromagnetic induction to detect flaws
in conductive
materials. Eddy current inspection can be performed with a minimum of part
preparation and a high degree of sensitivity. Eddy current testing is an
electromagnetic technique and can only be used on conductive materials. When we
do this practical the surface of the material must be accessible, the finish of
the material may cause bad readings, the depth of penetration into the material
is limited, and flaws that lie parallel to the probe may be undetectable.
Eddy currents are electrical currents induced in a conductor of electricity by reaction with alternating magnetic field. This form of testing relies on the attraction of magnetic particles to the flux leakage when an eddy current is passed through the material, this is an indication of the flaws existence, this flux leakage is caused by the flaw in the ferromagnetic material for which is being tested. Changes in the geometry & homogeneity of the test object will change the magnitude & distribution of the eddy currents. By monitoring these changes, the presence of cracks & other flaws can be detected. Commonly this method used in the aerospace, automotive, marine, and manufacturing industries.
3. Magnetic
Particle Testing
Magnetic
particle inspection processes are non-destructive methods for the detection
of surface and sub-surface defects in ferrous
materials. They make use of an externally applied magnetic
field or half-wave DC (rectified AC) current through the material,
and the principle that the magnetic susceptibility of a defect is
markedly poorer (the magnetic resistance is
greater) than that of the surrounding material.
The presence of a surface or near
surface flaw (void) in the material causes distortion in the magnetic flux
through it, which in turn causes leakage of the magnetic fields at the flaw.
This deformation of the magnetic field is not limited to the immediate
locality of the defect but extends for a considerable distance; even through
the surface and into the air if the magnetism is intense enough. Thus the size
of the distortion is much larger than that of the defect and is made visible at
the surface of the part by means of the tiny particles that are attracted to
the leakage fields.
The most common method of magnetic
particle inspection uses finely divided iron or magnetic iron oxide
particles, held in suspension in a suitable liquid (often kerosene).
This fluid is referred to as carrier.
The particles are often colored and usually coated with fluorescent
dyes that are made visible with a hand-held ultraviolet
(UV) light (sometimes referred to as black
light). The suspension is sprayed or painted over the magnetized
specimen during magnetization with a direct current or with an electromagnet,
to localize areas where the magnetic field has protruded from the surface. The
magnetic particles are attracted by the surface field in the area of the defect
and hold on to the edges of the defect to reveal it as a buildup of particles.
This inspection can be applied to raw
material in a steel mill (billets or slabs), in the early stages of
manufacturing (forgings, castings), or most commonly to machined parts before
they are put into service. It is also very commonly used for inspecting
structural parts (e.g., landing gear) that have been in-service for some time
to find fatigue cracks.
Usually tested pieces needs to be
demagnetizated by a degaussing tool before use. Parts are demagnetized by applying
AC current through the part which scrambles the magnetic domains causing it to
demagnetize
It is a quite economic non-destructive test because it is easy to
do and much faster than ultrasonic testing and testing. There are two
different ways of magnetizing a part Longitudinal and Circular magnetization.
Longitudinal Magnetization passes current through a coil and the magnetic flux
lines go through the part. Circular magnetization passes current through the
part and establishes a magnetic field around the part. The two different
methods are used because cracks can only be seen 45 to 90 degrees to the magnetic
flux lines. Magnetic Particle Inspection cannot be used for non-ferrous
materials and austenitic stainless steels. In such cases, other methods such as
dye penetrant inspection
are used.
4. Radiographic
Testing
This method of weld testing makes use
of X-rays, produced by an X-ray tube, or gamma rays, produced by a radioactive
isotope. The basic principle of radiographic inspection of welds is the
same as that for medical radiography. Penetrating radiation is passed
through a solid object, in this case a weld rather that part of the human body,
onto a photographic film, resulting in an image of the object's internal
structure being deposited on the film. The amount of energy absorbed by
the object depends on its thickness and density. Energy not absorbed by
the object will cause exposure of the radiographic film. These areas will
be dark when the film is developed. Areas of the film exposed to less
energy remain lighter. Therefore, areas of the object where the thickness
has been changed by discontinuities, such as porosity or cracks, will appear as
dark outlines on the film. Inclusions of low density, such as slag, will
appear as dark areas on the film while inclusions of high density, such as
tungsten, will appear as light areas. All discontinuities are detected by
viewing shape and variation in density of the processed film.
Radiographic testing can provide a
permanent film record of weld quality that is relatively easy to interpret
by trained personnel. This testing method is usually suited to having
access to both sides of the welded joint (with the exception of double wall
signal image techniques used on some pipe work). Although this is a slow
and expensive method of nondestructive testing, it is a positive method for
detecting porosity, inclusions, cracks, and voids in the interior of
welds. It is essential that qualified personnel conduct radiographic
interpretation since false interpretation of radiographs can be expensive and
interfere seriously with productivity. There are obvious safety
considerations when conducting radiographic testing. X-ray and gamma
radiation is invisible to the naked eye and can have serious health and
safety implications. Only suitably trained and qualified personnel
should practice this type of testing
DISCUSSION
Different types of methods are used to
find the material defects. By examining the structure of the material and
modifying the structure of material through heat treatment or other means, can
control the properties of material such as the strength, hardness and
ductility.
The
following samples are tested in macro structure examination.
·
Longitudinal section through
a cast ingot
·
Longitudinal section of a
forge. Steel bolt
·
Transverse section of a
carburized low-carbon steel bar
We examined, there
are some impurities gather to the center of the casted object. It may cause to
fracture the cast ingot. In forging, the
metal undergoes in heavy tensile loads therefore the metal molecules are
arranged in different order we can see flow lines. These molecular arrangements
are caused to fracture the steel bolt. When we examine the carburized low
Carbon steel bar, we saw in surface Carbon content is high because in the
carburize process only the surface of the metal is carburized.
In Fracture surface examination, the
samples provided are tested. By this test, the kind of the fracture can be
identified. If the fracture surface,
·
Has cup and cone shape : - ductile fracture by
tensile loading.
·
Is sharp : -
brittle fracture. From Chevron patterns in surface,
We can decide the
cracks propagation direction
·
Have layers of fracturing
stages : - fatigue failure. This beach
marks called striations
Modification of structure in order to achieve desired properties
For many kind of testing,
it is needed to modify the specimen before doing the test. The methods like
Radiographic methods do not want this because in those we use Electromagnetic
radiations. Some methods like Dry penetrant test require such structure modification
to reveal the material properties.
In Dry penetrant method,
the surface of the element should be cleaned well. Otherwise when there is an
oil, grease or dust particle on the surface, the penetrant should not work. If
we dyed, we have to use a good lighting system and if used fluorescent we have
to use UV light. In magnetic particles, testing the specimen should be a
ferrous metal. However, there should be different kind of to magnetize the
component. More accuracy can obtain by an initial non-ferrous layer if exist.
In eddy, current testing
the specimen should be conductive. So we can use this method to ferrous and non
ferrous metals. There should be a good touch between the specimen and the
instruments. The voltage of the instruments varies with the dimension of the
specimen.
Application of
liquid penetrant test
·
Aircraft maintenance
·
Heat affect zone cracks
·
Poor weld penetration
·
Gas porosity
·
Cold shuts
·
Stress corrosion cracks
·
Heat treatment cracks
·
Fatigue cracks
·
Micro shrinkage
·
Grinding cracks
·
Hydrogen cracks
·
Inclusions
·
Hot tears
·
Laminations
Limitations of liquid penetrant test
v
Can detect very small surface discontinuity.
v
Frequently used to confirm suspected defects.
v
Area to be cleaned before and after check.
v
Generally restricted to ‘nonporous’ engineering
materials.
v
Fluorescent penetrates are used in critical
areas for more sensitive evaluation
v
Cracks not open to the surface cannot be
detected.
Applications of eddy current test:-
Ø
Detecting
surface-breaking or near-surface cracking and variations in material
composition.
Ø
Can be used to measure the thickness of
non-electrically conductive coatings on electrically conductive substrates.
Ø
Used in plant inspection for non-ferrite
materials (where eddy current penetration is deeper) or for special
applications, such as in the inspection of heat exchanger tubes for cracking or
corrosion thinning.
Comparison of Eddy Current test with Magnetic Inspection test:-
|
|
Eddy
current test
|
Magnetic particle
test
|
|
Advantages
|
Use for all conductive materials
|
Effective for defects of any shape
|
|
portable
|
Easily portable
|
|
|
Sensitivity is high
|
|
|
|
Disadvantages
|
Trained operator required
|
For Ferrous metals only
|
|
Separate probes required for variation of materials
|
Demagnetization procedure is required
|
USED OF THE TEST IN QUALITY
CONTROL
Ø The
eddy current method can be used as a quality control system. Because it can
easily detect defects in the surface. If we can introduce an automated system,
the defects are removed quickly.
Ø The
Dye penetrant method is normally used for small components. In industrial
level, it is often automated with series of and an inspection boot in with
mechanized handling, timing solution, agitation etc.
