1_Quizizz05.Intermediate Quality Control and Inspection Methods _compressed_organized.pdf

Transcript

WSS Study Guide WC2.1

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Intermediate Quality Control and Inspection Methods

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Lesson 1

Obiectives

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After completing this lesson you should be able to:
$ Define quality
$ Differentiate between destructive and nondestructive testing
$ Describe the following destructive test methods: tensile test, guided
bend test, hardness test , Impact test, nick-break test and fillet weld

$

fracture test
Identify details that can be observed by macroscopic examination of
welds

1. Quality and Quality Control
What is Quality?
When asked to define quality, our definition will most likely focus on the
quality of our lives, on the quality of our environment, or, we may focus
on the quality of the products and services we use. There are as many
definitions of quality and each person's definition will differ depending on
the individuals perception of quality.
Quality must, however, be important to each of us because the issue has

inspired and challenged many authorities to define it for us. Even current
authorities focusing on the quality of products and services differ in their
perceptions and definitions:
Crosby “Quality is defined as conformance to requirements, not as
goodness”
Deming “Quality means the effective production of the qualitv that the
market expects; it does not mean achieving perfection.”

Juran “Quality is fitness for use.”
1SO “degree to which a set of inherent characteristics fulfils requirements”
(inherent means existing in something, especially as a permanent
characteristic)
Other “Right first time, every time, at an acceptable cost”

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WSS Study Guide WC2.1
Intermediate Quality Control and Inspection Methods

Quality as defined by organizations who have successfully implemented
and maintained a quality management system based on ISO requirements
is “Return on investment for ensuring customer satisfaction through
continual improvement of product, processes and quality management
system.”

What does “Quality” mean to vou?
In comparing definitions of quality, vou may discover one common
element. The one common element is the concept of meeting, satisfying

or complying with needs, requirements and expectations.
The quality of a weld may be defined as “the welds ability to perform
reliably throughout its intended service life.”
The welder and the supervisor are most concerned with the standard of
workmanship that forms part of the overall weld quality. Workmanship is

controlled at the shop floor or in the field and depends on the skill of the
welder and the experience of the supervisor.

A discontinuity is an interruption of the typical structure of a material,
such as lack of homogeneity ïn ïts mechanical, metallurgical or physical
characteristics. A discontinuity is not necessarily a defect.
A defect is a discontinuity or discontinuities that by nature or accumulated
effect render a part or product unable to meet minimum applicable

acceptance standards or specifications. The term designates rejectability.
It is important to consider the type and quantity of discontinuities,

the type of weldment and the service conditions in determining if a
discontinuity is a defect. The same discontinuity may be considered a

discontinuity for one application and a defect for another. For example,
a measured depth and length of undercut may be a discontinuity under
static loading and a defect under cyclic loading. A crack ïs always a defect.
Inspection test methods may be categorized as: Destructive testing, the
process of destroying the completed weld to evaluate ïts characteristics
and nondestructive testing (NDT), where a component or assembly is

evaluated without damaging or otherwise lessoning its intended service
life.

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WSS Study Guide WC2.1
Intermediate Quality Control and Inspection Methods

2. Destructive Test Methods
2.1 Tensile Tests
When a metal is subjected to an external force, the force will be resisted
by internal forces within the metal. The intensity of these forces through a
given plane is khown as a stress. In a simple example, consider a round rod

subject to a load of 1000 N (newtons) as shown ïn Figure 1. The uniform
stress in the rod is given by the load divided by the cross-sectional grea
oƒ the rod.

1000 N
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Rod subject to tensile load

The strain in a body is a measurement of the change in dimensions due to
the application of an applied load. If a bar of gauge length L ïs stretched
by an amount e, then the strain (e) is the extension divided by the original
length.

lf a thin bar of metal is subject to a stress, ït will deform and exhibit a
strain. lf the stress does not exceed a certain limit, the bar wïll return to

its original dimensions when the stress is removed. This is khown as elastic
behaviour.

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Intermediate Quality Control and Inspection M ethods

lf a sufficiently high stress is applied to a bar, it will not return to its
original length when the stress is removed. In this case, where the bar has
undergone plastic deformation, the residual strain left when the stress is

removed is khown as a permanent set.
In some metals, the change from elastic to plastic behaviour is gradual,

with the stress-strain plot being a smooth curve.
In metals showing a smooth change, there is no obvious point to take for
the yield point. The yield stress is therefore defined as the stress at which
a given permanent set is recorded (usually 0.2%).

Stress (ơ) Ạ
yield point

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loading

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0.2 % permánent strain

(0.2% offset)
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IMegsuring yield strength by ø 0.2% offset method

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Strain (€)

WSS Study Guide WC2.1

mg
P' 2

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Intermediate Quality Control and Inspection Methods

In many steels, however, there is an abrupt change from elastic to plastic
behaviour and the stress-strain curve appears as shown in Figure 3.

Typical stress-strain curve for steel
Ultimate tensile strength UTS)

s

Yield point(ơ)---+---

Breaking stress

Stress(ơ)

Strain(€)

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Typical stress-strain curve for steel

Ifloading of the bar is
complete stress-strain
in Figure 3. The stress
tensile strength (UTS)

continued the specimen will eventually break. The
curve for steel will then appear typically as snown
rises to a maximum value known as the ultimate
then decreases until the specimen finally breaks.

The tensile test involves loading a standard test specimen in tension unti|
the specimen fails.
A number of mechanical properties can be determined from a tensile test,

including the following that are significant in welding:
$

Yield strength (the stress at which permanent deformation occurs)

$

Ultimate strength (the highest stress that the material is able to
withstand)

$

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Ductility (percentage elongation or reduction of area of a defined
segment of the specimen)

WSS Study Guide WC2.1

Intermediate Quality Control and Inspection Methods

To carry out tensile tests, special machines are needed to exert the

necessary force in a controlled manner. They are generally of two types:
mechanical and hydraulic. In both types, there is one fixed crosshead and
a second, moving crosshead that applies the force and the specimen is
held in special grips connected to the crossheads.

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Typical tensile testing machine

WSS Study Guide WC2.1

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Intermediate Quality Control and Inspection Miethods

There are a number of standard tensile specimens of various sizes and
shapes, but only the two most commonly used in the testing of welds
will be discussed. They are:
$

Ali-weld-metal tensile test specimen. This is used primarily in the
classification of welding consumables and is designed to test the

tensile properties of a weld deposit made under standard conditions.
$

Transverse weld test specimen. This is used in the qualification of
welding procedures and is designed to test the strength of the welded
joint as a whole, including the weld metal, heat-affected zone and base

metal.
Figure 5 shows the specimen normally used for all-weld-metal tensile

tests. The diameter is normally 12.5 mm, which gives a cross-sectional
area of 122.7 mm and this simplifies the calculation of the stress. In
practice, a tolerance is given on diameter and the actual value would be
used to calculate the cross-sectional area.
Specimens with either threaded ends or with shouldered ends can be
used. The gauge length is marked by two pop marks and this facilitates
the measurement of final length when the broken halves are placed back
together.
The location of the specimen relative to the weld ïs shown in Figure 5.
The transverse weld test specimen ïs used mainly in the qualification of
welding procedures. Specimens have a square or rectangular cross-section
and are prepared transverse to the weld. This means that the base metal,

heat-affected zone and weld metal are tested.
Unlike the all-weld-metal tensile specimen that only samples some of the
weld metal, the transverse weld test specimen ïs intended to represent
the entire cross-section of the weld. Thus, the specimen thickness is equal
to the thickness of the welded plates and only the weld reinforcement is
removed.
Before
section
tensile
during

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testing, the least width and corresponding thickness of the reduced
are measured to calculate the cross-sectional area. The ultimate
strength is determined by dividing the maximum load reached
the test by the cross-sectional area.

WSS StudyiGuide WC2.1

Intermediate Quality Control and Inspection Methods

All-weld-metal specirnen
Reduced Section
60 mm min.

+01

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50 mm

# 0.1mm

All-weld-metal specimen

Centreline of the weld
Transverse tensile specimen

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All-weld-metal and transverse tensile specimens

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Intermediate Quality Control and Inspection Methods

2.2 Guided Bend Test
The guided bend test is used in welder and procedure qualification to
determine the ability of a welder to make sound welds or the suitability
ofawelding procedure. The test is carried out by preparing specimens
transverse to the weld and bending them in a special jig, the dimensions
of whiïch vary with specimen thickness and material strength.
A typical plunger-type jig used for bend tests is shown in Figure 6. Notice
that the strain applied to the specimen depends on the spacing of the
rollers and the radius of the plunger. The bending of higher strength steels
requires a larger radius to reduce applied strain.

As required

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As required

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170 mm

¡——Plunger

Material Yield | -AStrength - MPa

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345 & Under

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over 345 to 620

50

over 620

63.5

36.5
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Plunger-type guided bend test jig

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WSS Studý Guide WC2.1
Intermediate Quality Control and Inspection Methods

The wrap-around-type guided bend test jig shown in Figure 7 is useful
where the strength and particularly the ductility of the weld zone differs
greatly from the unaffected parent material.

Roller (any
diameter)

vì

ì

Z

`7: Weld

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B=ZA

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Material

Yield Strength (MPa)*
345 and under

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Over 345 to 620

50

25

Qver 620

63.5

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* Minimum specified

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Wrøp-around guided bend test jig

Care must be exercised in the preparation of the bend samples. To prevent

stress raisers and premature failure, the edges should be radiused and all
grinding marks should be parallel to the length of the specimen.
After bending, the specimens are examined for discontinuities. It is a
condition of many codes, such as CSA Standard W47.1, that the specimens
shall be considered to have failed ïf, on examination of the convex surface
after bending, there is a crack or open defect exceeding 3 mm in length

measured in any direction. The maximum permitted size of a corner crack
Is 6 mm, except when it resulted from visible slag inclusions or other

fusion-type discontinuities, in which case the maximum permitted size
is3 mm.

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Intermediate Quality Control and Inspection Methods

Acceptable and unacceptable bend tests are shown in Figure 8.

Incomplete
Tusion

Succesful bend
specimen
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Failed bend
specimen

Acceptable and unacceptable bend tests

Guided bend tests are of three types: root-bend, face-bend and side-

bend. Root-bends and face-bends are generally used when the material
thickness is 10 mm or less. On material over 10 mm, side-bends are
normally chosen due to the difficulty of performing root- and face-bends
on material of sụch thickness. All side-bend specimens are 10 mm wide
regardless of thickness.
In the face-bend, the specimen is bent so that the face of the weld is
in tension—the face ïs on the outside curvature so that ït is under the

greatest tensile stress.
In the root-bend, the specimen is bent so that the root of the weld is in
tension. This test is very effective ïn revealing any incomplete penetration

or incomplete fusion at the root of a one-sided weld.
In the side bend, a narrow test specimen is cụt across the welded joint.
The specimen is then bent sideways so that the tension forces tend to pull

the weld metal away from the parent metal over the entire depth of the
weld as shown in Figure 9. This test is preferred for double-V-groove welds

since internal defects at the root are more likely to be revealed.

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WSS Study Guide WC2.1
Intermediate Quality Control and Inspection Methods

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Example oƒ a bent side-bend specimen

2.3 Hardness Test
Hardness is the ability of a material to resist permanent or plastic
deformation.
Hardness testing is a common method of testing metals and ït is easily
and economically performed. There is a relationship between hardness

and some of the mechanical properties of steel and the tensile strength
of steel will vary in close relation to its hardness. High hardness means
high strength and low hardness, low strength. Usually, a high hardness

also indicates low ductility.
Generally speaking, hardness testing is an indentation test whereby a
penetrator of a given material, shape and size is forced into the surface

of the material being tested by a given load. The degree of hardness is
indicated by the depth penetrated or by the area of resulting impression.
The Brinell, Vickers and Rockwell hardness tests operate on this principle.

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Brinell Hardness Test
The Brinell hardness tester usually consists of a vertically mounted
hydraulic cylinder, which is used to force a ball into the surface of the
metal to be tested, as shown in Figure 10. For steel, the ballis 10mm
(0.394 in) in diameter, the force applied ïs 3000 kg (6600 lb) and the force
is maintained for 30 seconds. The diameter of the iImpression is read and

the Brinell number can be calculated from this.

Force = 3000 kg

¬—10 mm diameter

RG10,

Brinell hordness test

A limitation of this test is that the size of the indentor prevents testing
ïn narrow areas of the weld, such as the heat-affected zone. The Brinell

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hardness value is designated by the letters HB.

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Intermediate Quality Control and Inspection Methods

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Rockwell Hardness Test
The Rockwell hardness tester, as shown in Figure 11, determines the

hardness by measuring the depth of penetration of an indentor under
a large load compared to the penetration made by a preload. There
are different scales, which are denoted by a single letter, and these use
different loads or indentors. Readings are expressed by HRx, where x
represents the scale (e.g., HRC 62 is 62 on the Rockwell C scale).

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Rockwell hardness tester

The two most commonly used scales in testing welds are the Rockwell C
and the Rockwell B. In the Rockwell C, a major load of 150 kg is used and
the indenter is a conical-shaped diamond. In the Rockwell B, the major
load is 100 kg and a 1/16 in steel ball ïs used for the indenter.
A Rockwell test is made by elevating a specimen against the indenter

until a minor load is applied. When this load is applied, the dial indicator
is adjusted to a “set” position. The major load is then applied and the
loading rate and time of application are governed by the machine.
On completion of the application, the major load is removed and the
hardness number is read directly from a dial indicator.

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Imtermediate Quality Control and Inspection Methods

Diamond cone indenter

Depth to which indenter
=>

1s forced by major load

Depth to which
indenter is forced by

minor load

Surface of specimen X

=>

Increment in depth due to
inerement in load is the linear measurement
that forms the basis of the Rockwell hardness

testreadings

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Rockwell hardness test

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Since
rapid
to be
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Vickers Hardness Test

it is not necessary
results. However,
used for thin test
be approximately

to measure the indentation, this method delivers
the large load applied does not permit this method
pieces. A typical requirement is that the testpiece
10 times the depth of the indentation.

The Vickers hardness tester, as shown in Figure 13, is widely used for

testing welds because the size of the indentaftion is small and it is relatively
easy to locate specific regions of the weld such as the weld metal, heataffected zone and base metal. It has the advantage that a wide range of
loads can be used to cover materials from very soft to very hard using the
same indenter. However, this method has the same disadvantage as the

-

Brinell test because the size of the indentation has to be measured.

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Intermediate Quality Control and Inspection Methods

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Vickers hardness tester

The indenter used is a square-based diamond pyramid and this is brought
to within 1 mm of the indenter and the loading mechanism is tripped.
The load is usually in the range 5-100 kg. When

performing testing, the

distance between each indentation should be no less than 25 times the
indentation size to avoid interaction between work-hardened regions.
When viewed through a microscope, the impression in the specimen
appears as a dark square. The diagonals of this square are measured
to give an ocular reading and from this the hardness number can be
calculated. Again, there are tables available that make calculation

unnecessary.
The unit of hardness given by the test is khown as the Vickers Pyramid
Number (HV). Figure 14 shows the Vickers hardness test.

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