1. BMFB 4283 NDT & FAILURE ANALYSIS
Lectures for Week 3
Prof. Qumrul Ahsan, PhD
Department of Engineering Materials
Faculty of Manufacturing Engineering

2. Issues to address 3.0 Magnetic Particle Testing 3.1 Introduction
3.1 Introduction
3.2 Theory
3.3 Techniques and Equipment
3.4 Inspection and Application

3. MAGNETIC PARTICLE TESTING - Outline
Magnetism and Ferromagnetic Materials
Introduction of Magnetic Particle Inspection
Basic Procedure and Important Considerations
Magnetizing methods and apparatus
The detecting medium
Examples of MPI Indications
Reporting Indications
This presentation was developed to provide students in industrial technology programs, such as welding, an introduction to magnetic particle testing. The material by itself is not intended to train individuals to perform NDT functions but rather to acquaint individuals with the NDT equipment and methods that they are likely to encounter in industry. More information has been included than might necessarily be required for a general introduction to the subject as some instructors have requested at least 60 minutes of material. Instructors can modify the presentation to meet their needs by simply hiding slides in the “slide sorter” view of PowerPoint.”
This presentation is one of eight developed by the Collaboration for NDT Education. The topics covered by the other presentations are:
Introduction to Nondestructive Testing
Visual Inspection
Penetrant Testing
Radiographic Testing
Ultrasonic Testing
Eddy Current Testing
Welder Certification
All rights are reserved by the authors and the presentation cannot be copied or distributed except by the Collaboration for NDT Education.
A free copy of the presentations can be requested by contacting the Collaboration at

4. Introduction
This module is intended to present information on the widely used method of magnetic particle inspection.
Magnetic particle inspection can detect both production discontinuities (seams, laps, grinding cracks and quenching cracks) and in-service damage (fatigue and overload cracks).

5. Magnetic Particle Testing
Test method for the detection of surface and slightly sub-surface indications in ferromagnetic materials MT MT
Subsurface
Surface Defect
Ferromagnetic Material
Internal
CANNOT BE DETECTED BY Magnetic Particle Testing

6. Introduction to Magnetism
Magnetism is the ability of matter to attract other matter to itself. Objects that possess the property of magnetism are said to be magnetic or magnetized and magnetic lines of force can be found in and around the objects. A magnetic pole is a point where the a magnetic line of force exits or enters a material.
Magnetic field lines:
Form complete loops.
Do not cross.
Follow the path of least resistance.
All have the same strength.
Have a direction such that they cause poles to attract or repel.
Magnetic lines of force around a bar magnet
Opposite poles attracting
Similar poles repelling

7. Ferromagnetic Materials
A material is considered ferromagnetic if it can be magnetized. Materials with a significant Iron, nickel or cobalt content are generally ferromagnetic.
Ferromagnetic materials are made up of many regions in which the magnetic fields of atoms are aligned. These regions are called magnetic domains.
Magnetic domains point randomly in demagnetized material, but can be aligned using electrical current or an external magnetic field to magnetize the material.
Magnetized
Demagnetized S N

8. Domain Theory UNMAGNETISED STATE DOMAINS RANDOMLY ORIENTATED
MAGNETIZED STATE.
DOMAINS ORIENTATED IN EXTERNAL
MAGNETIC FIELD
FIELD
SATURATED STATE
DOMAINS ORIENTATED IN STRONG
EXTERNAL FIELD
FIELD

9. Domain Theory RESIDUAL STATE. DOMAIN REMAINING ORIENTATED
DEMAGNETISED STATE.
DOMAINS RANDOMLY ORIENTATED IN
OPPOSING CURVE
FIELD

10. How Does Magnetic Particle Inspection Work?
A ferromagnetic test specimen is magnetized with a strong magnetic field created by a magnet or special equipment. If the specimen has a discontinuity, the discontinuity will interrupt the magnetic field flowing through the specimen and a leakage field will occur.

11. How Does Magnetic Particle Inspection Work? (Cont.)
Finely milled iron particles coated with a dye pigment are applied to the test specimen. These particles are attracted to leakage fields and will cluster to form an indication directly over the discontinuity. This indication can be visually detected under proper lighting conditions.

12. Principle of MT : Flux Leakage
Ferromagnetic Particles
Ring Magnet
Ring Magnet
Flux Leakage N S
Attracted at poles
Magnetic field is Fully contained: No Poles
Flux Leakage occurs: Poles created

13. Principle of MPI : Flux Leakage
No Defect
Defect
Flux Leakage N S N S
The change in permeability causes flux leakage

14. Principle of MPI : Flux LeakageS
STEEL µ= 1000
No Flux Leakage because No change in permeability

15. Principle of MPI : Flux LeakageS
AIR µ= 1
STEEL µ= 1000
The change in permeability causes flux leakage

16. Factors Affecting Flux Leakage
Depth of defect
Orientation of defect shape of defect
Size of defect
Permeability of material
Amount of flux available

17. Factors Affecting Flux Leakage
Depth below surface
Depth of defect
Orientation of defect shape of defect
Size of defect
Permeability of material
Amount of flux available

18. Basic Procedure Basic steps involved: Component pre-cleaning
Introduction of magnetic field
Application of magnetic media
Interpretation of magnetic particle indications

19. Pre-cleaning
When inspecting a test part with the magnetic particle method it is essential for the particles to have an unimpeded path for migration to both strong and weak leakage fields alike. The part’s surface should be clean and dry before inspection.
Contaminants such as oil, grease, or scale may not only prevent particles from being attracted to leakage fields, they may also interfere with interpretation of indications.

20. Introduction of the Magnetic Field
The required magnetic field can be introduced into a component in a number of different ways.
Using a permanent magnet or an electromagnet that contacts the test piece
Flowing an electrical current through the specimen
Flowing an electrical current through a coil of wire around the part or through a central conductor running near the part.

21. Direction of the Magnetic Field
Two general types of magnetic fields (longitudinal and circular) may be established within the specimen. The type of magnetic field established is determined by the method used to magnetize the specimen.
A longitudinal magnetic field has magnetic lines of force that run parallel to the long axis of the part.
External solenoidal coil
With yoke
A circular magnetic field has magnetic lines of force that run circumferentially around the perimeter of a part.
Head Shot
Central conductor
Prod

22. Importance of Magnetic Field Direction
Being able to magnetize the part in two directions is important because the best detection of defects occurs when the lines of magnetic force are established at right angles to the longest dimension of the defect.
This orientation creates the largest disruption of the magnetic field within the part and the greatest flux leakage at the surface of the part.
An orientation of 45 to 90 degrees between the magnetic field and the defect is necessary to form an indication.
Flux Leakage
No Flux Leakage
Since defects may occur in various and unknown directions, each part is normally magnetized in two directions at right angles to each other.

23. Defect Orientation
Defect at 90 degrees to flux : maximum indication

24. Defect Orientation
>60 Degrees to Flux: Acceptable indication

25. Defect Orientation
<60 Degrees to Flux : Weak indication

26. Question
? From the previous slide regarding the optimum test sensitivity, which kinds of defect are easily found in the images below?
Longitudinal (along the axis)
Transverse (perpendicular the axis)

27. Induction methods Threaded bar Flexible cables
Hollow object must have access both ends
Conductor carrying current is threaded through bore passed current through it.
Produced circular field
Flexible cables
Used for a variety component shape
Place flexible cable on or around specimen
Current passed through coil induce magnetic field

28. Producing a Longitudinal Magnetic Field Using a Coil
A longitudinal magnetic field is usually established by placing the part near the inside or a coil’s annulus. This produces magnetic lines of force that are parallel to the long axis of the test part.
Coil on Wet Horizontal Inspection Unit
Portable Coil

29. Magnetizing methods – Induction methods
Encircling coils
Placing specimen inside coils
Low voltage, high amperage current is passed
Creates longitudinal magnetic field
Current values:
NI = K/[L/D]
N = number of turns in the coils
I = current in amperes
L = the component length
D = the component diameter
L/D = ratio of geometrical information of component
K = source constant ( K= 32 for DC, 22 for AC, 11 for mean value)

30. Flexible cable technique
Advantages:
AC or DC field
Large areas can be inspected
No poles to attract magnetic particles
Filed strength can be altered
Predictable field strength
Disadvantages:
Cumbersome long heavy cable required
Longer setting time
Heavy transformer required for large amperage

31. Producing a Longitudinal Field Using Permanent or Electromagnetic Magnets
Permanent magnets and electro-magnetic yokes are also often used to produce a longitudinal magnetic field. The magnetic lines of force run from one pole to the other, and the poles are positioned such that any flaws present run normal to these lines of force.
Yokes:
Highly permeable, low retentive steel
Laminated to reduce induction and prevent the yoke from permanently magnetized

32. Electromagnetic yokes
Magnetism:
Encircling yoke with coil through which current is passed
Strength of field is varied by:
Adjusting the current (amperage) flowing through the yoke
Varying the distance between the pole pieces
The field produced is longitudinal
Depth of field depends on type of current
Require source of electrical energy (AC or DC)
Surface discontinuities using AC
Sub-surface defect using DC

33. Electromagnetic yokes
Advantages:
AC or rectified DC operation
Controllable field strength
Can be switched on/off as required
No damage done to test piece
Relatively lightweight
Disadvantages:
Requires power supply
Only small area can be examined
Leaves only one hand free

34. Magnetizing methods - Permanent magnet
able to maintain a magnetic field in surrounding space
Field strength can vary considerably, depends on flux density in magnet and shape
Magnetic bar:
A piece of ferromagnetic material with a magnetic pole at each end
Placed into a closed loop:
create magnetic field within closed circuit and no external field would exist
If defect present in the loop, flux leakage occur
Provide magnetic flow in the specimen and produce longitudinal magnetic field between poles

35. Permanent magnets Advantages: Disadvantages: No power supply required
Inexpensive
No damage to the test piece from arcing
Relatively lightweight (portable)
Disadvantages:
Deterioration with wear
Have to be pulled from the test surface
Magnetic particles attracted to poles
Limited application on awkward shapes

36. Circular Magnetic Fields
Electric
Current
Circular magnetic fields are produced by passing current through the part or by placing the part in a strong circular magnet field.
A headshot on a wet horizontal test unit and the use of prods are several common methods of injecting current in a part to produce a circular magnetic field. Placing parts on a central conductors carrying high current is another way to produce the field.

37. Magnetizing methods – Current flow
Produce circular magnetic field by passing current through test piece
Prod technique
Current is introduced using electrical contacts (prod)
Prod induce circular magnetic field within specimen using current values
Correct positioning is essential to ensure all possible defects are detected
Ideally the prods should be in line parallel to or on the same axis as the defect

38. Current flow - Prods Advantages: AC or DC fields Low voltage output
No poles to attract magnetic particles
Variable field strength
Can be used in confined spaces
Disadvantages:
Risk of creating arc strikes
Heavy transformer required
Contacts and small test items can be overheated
Careful positioning and spacing of prods are required

39. Longitudinal vs. Circular Magnetic Field
Longitudinal Magnetic Field
Circular Magnetic Field
Advantages
Easy to generate
Higher field strength
No electrical contacts
Wholly contained within the part
Rapid processing of small and long part
Penetrating power is more
Easy to demagnetize part
Disadvantages
Lower field strength than circular
Difficult to remove circular DC fields
Generates nonrelevant poles at the part ends
Electric contact and associated with arcs
Very little subsurface sensitivity

40. Types of Magnetization Current
DC, AC, HWDC, 1FWDC, 3FWDC
Type of current used depends primarily on the depth of the defect from the surface, not the crack size
AC provides a highly concentrating field at the parts surface ( detecting surface and very near surface defects)
Alternating magnetic field increases particle mobility and particles attract to leakage field(dry powder with HWDC)
A time varying magnetic field induces eddy current within the material. Eddy currents cause the magnetic field to decay exponentially .
The depth  is the skin depth, where the magnetic field is 37% of its maximum value. = 1/πµf
DC penetrates deeper, provides both moderate surfaces and subsurface sensitivity.

41. Magnetic Particles
Fine magnetic particles that create an indication at a leakage field caused by a flaw in the magnetized sample
Depending on its characteristics and application
Type of particle (dry or wet)
Viewing method (color contrast or fluorescent)
Method of application (continuous or residual)

42. Requirement of magnetic particles
Fine grains to reduce the gravitational effect. The maximum size (BS 4069): 200m for powder and 100 m for inks
Particles are chemically treated iron oxide particles, small in size and varying in shape (spherical to irregular  sensitive to flaw)
Elongated shape for easier polarization. Spherical particles are also needed to ensure dispersal over the surface
High magnetic permeability and low retentivity (avoid to become permanent magnet)
High permeability for magnetization in weak flux leakage fields
Low retentivity if particles are to be removed after the test
High contrast against the background of the test surface

43. Dry Magnetic Particles
Magnetic particles come in a variety of colors. A color that produces a high level of contrast against the background should be used.
May be black, grey, red, orange, fluorescent
Usually applied to a surface by means of puffer device:
They should be floated, not blasted on to the
area under test
the particles are lightly dusted on to the
surface
Should be ideally be used with ac or dc current
Because of extra mobility of the current
impart onto powder
Must be used when MPI is being carried out on
hot and rough surfaces
Inks are not suitable
The dry method is more portable

44. Wet Magnetic Particles
Wet particles are typically supplied as visible or fluorescent. Visible particles are viewed under normal white light and fluorescent particles are viewed under black light.

45. Wet Magnetic Particles
According to BS 4069, the composition of inks shall be:
Ferromagnetic particles in non-fluorescent inks should not be less than 1.25% and not more than 3.5% by volume
Ferromagnetic particles in fluorescent inks should not be less than 0.1% and not more than 0.3% by volume
Carrier fluid may be oil based: paraffin or water to make up volume by 100%
If water is used, additives shall be added to prevent corrosion on the surface or the particles and improve the wetting action
With the wet method, the part is flooded with a solution carrying the particles.
The wet method is generally more sensitive since the liquid carrier gives the magnetic particles additional mobility.

46. Viewing conditions Non-fluorescent inks and powders:
Area under inspection must be evenly illuminated
Min illumination level of 500 lux (daylight/artificial light)
Fluorescent inks and powders:
Min UV-A irradiance level: 800 W/cm2, min background intensity 10 lux
Degrade with exposure to ordinary light over a period of time and high temperature
UV intensity increases, the amount of fluorescent increases too

47. UV-A light Generated by mercury vapor lamps
Mercury is vaporized inside a quartz capsule by small low current arc from auxiliary electrode
After 5 minutes, there is sufficient mercury vapor in the capsule to initiate between main electrode
The lamp should be used after 15 minutes to allow sufficient time to attain full working intensity

48. Safety UV light operate with wavelengths between 320 – 400 nm
Shorter wavelength cause injury to the eyes
Filter must be used which cut wavelength under 320 nm to prevent injury
Looking into UV-A cause temporary clouding vision
 fluid in the eyeball fluorescing
 will normalize with no permanent effects after few seconds
Prolonged exposure may cause cataract

49. Health Flammability: Asthmatic: Skin hazard:
Read container labels for flash points. Materials cannot be used under flash points
Asthmatic:
Do not use in confined space without masks or adequate ventilation
Skin hazard:
Use protective clothing

50. Methods of Application
Continuous method : apply particles to all surfaces of the part while the part is being magnetized
Rather easy for dry powder
For wet powder parts are magnetised several time with short duration (0.5 sec)
Residual Method: apply the particle after magnetizing has been removed
Residual force must be large
Suitable for wet part and defects under plating or coating
less sensitive

51. Relative Penetration Sensitivity
Current Type vs. Wet or Dry Method AC HW
DC (1FWDC & 3FDC)
Penetration
Poor
Excellent
Good
Wet Method
Surface and near surface to 0.25 mm
Surface and near surface to 0.65 mm
Surface and subsurface to 1.3 mm
Dry Method
Surface and near surface to 0.25mm
Surface and subsurface to 6.35 mm

52. Inspection Aids Controlling particle suspension
Changes in particle concentration
The acceptable operating range for fluorescent particles is ml in 100 ml of liquid
Below 0.1 ml – too low to detect small defects
Above 0.4 ml –background fluorescrnce may mask small defects
Loss of fluorescence
Contaminations
Water in oil bath or vice versa
Excessive wetting agent
Agglomeration reduces mobility
Centrifuge tube

53. Inspection Aids Controlling magnetization and system performance
Hall Effect Meter: measures the amplitude of either an AC or a DC magnetic field
Pie Gauge : made by brazing together six pie-shaped pieces of high permeability, low retentivity material
Ketos Test Ring : A centered hole circular disk with several small drilled holes at varying depth to check leakage flux of circular field.
Avoiding non relevant indication

54. Indications
Relevant Indications - Indications due to discontinuities or flaws
Non-Relevant Indications - Indications due to flux leakage from design features
Spurious Indications - Indications due incorrect inspection procedures

55. All surface defects form indications
But not all indications are caused by defects
Splines
Furring
Rough Surface
Non-relevant indications
Due to flux leakage but arising from design features or geometry
Changes in section
Changes in permeability
Furring
Toe of welds
Keyway
Rivet

56. Furring
Caused by:
Sharp change of contour
Furring
Furring

57. Furring Caused by: Excessive flux on the surface or ends of component

58. Magnetic Writing Caused by:
Localised polarization when magnetised object induced the magnetic field into another object

59. Spurious / False Indications
Indications caused by operator errors
Not due to flux leakage
Lint
Dirt
Hairs

60. Relevant Indications
Indications caused by defects

61. Magnetic Particle Testing
Cracks indications by Fluorescent Ink

62. Crane Hook with Service Induced Crack
Fluorescent, Wet Particle Method

63. Gear with Service Induced Crack
Fluorescent, Wet Particle Method

64. Drive Shaft with Heat Treatment Induced Cracks
Fluorescent, Wet Particle Method

65. Splined Shaft with Service Induced Cracks
Fluorescent, Wet Particle Method

66. Threaded Shaft with Service Induced Crack
Fluorescent, Wet Particle Method

67. Large Bolt with Service Induced Crack
Fluorescent, Wet Particle Method

68. Crank Shaft with Service Induced Crack Near Lube Hole
Fluorescent, Wet Particle Method

69. Lack of Fusion in SMAW Weld
Indication
Visible, Dry Powder Method

70. Toe Crack in SMAW Weld
Visible, Dry Powder Method

71. Throat and Toe Cracks in Partially Ground Weld
Visible, Dry Powder Method

72. Reporting
Adequate reporting is essential for transmission of relevant and correct information after the test
Minimum requirement:
Work location
Description and identity of the component tested
Date of test
Stage of test
Reference to the written test procedure and the technique sheets used
Name of the company
Name and signature of the person performing the test
The test results

73. Reporting
If written procedure is absent: these information must be supplied:
Description of equipment used
Technique of flux generation
Indicated current values and waveform for each technique used
Distance between contact areas of dimensional details of the coils
Detection medium used and background
Surface preparation
Viewing condition
Method of recoding or marking indications

74. Method of recording indications
Common method:
Reproduce indications on a scaled diagram.
Indications drawn with references to a datum on test piece
The diagrams should not be overloaded with too much information
Separate diagram show the magnetization techniques

75. Method of recording indications
Other methods:
Photographs
Clear sticky tape to peel the dried magnetic particles indication from the test piece
Propriety lacquers sprayed on wet; when dry the resultant film is then peeled away with the indication
Magneto-graph
Magnetic sachets with light sensitive paper backings

76. Preservation of indications
To maintain permanent record, one of these methods can be used:
Cover the indications with a transparent adhesive film. Carefully peel off the film and the adhering indications and reapply to either paper or card of contrasting color.
Degrease the test surface, cover with a white matt adhesive film and retest. After drying, if necessary, cover the indications with a clear film as in method describe above.
Spray the tested area with a quick-drying, strippable coating. Strip off this coating and view the face previously in contact with the workplace to which the indications will be transferred.

77. Preservation of indications
Heat the work place to an approved temperature and, without delay, slowly immerse in a powdered plastic material and slowly withdraw. Allow it to drain and cure it in accordance with the manufacturers instructions. Strip off the coating complete with the indications from the work piece and view the face previously in contact with it
Degrease the test surface and coat with a proprietary, strippable, magnetic-oxide paint. Magnetize the part to saturation and peel off the coating. If it is dipped in agitated magnetic ink, it will reveal the flaw indications on the oxide film.
Degrease the test area and coat the test area with a proprietary, self curing magnetic silicone-rubber compound. Magnetize to saturation and allow the compound to cure. The oxide in the compound will migrate to the position of nay flaw and when removed from the work piece, the rubber previously in contact with the surface will show the flaw

78. Photographic records
When photographic record is made, the resulting photograph of tested surface should be, if possible, the actual size
If the surface is highly polished, care should be taken to avoid highlights
The use of matt contrast medium applied prior to testing may be desirable

79. Surface preparation Dry powder: Wet powder:
No preparation is necessary
Wet powder:
Drained surface or adequately dried
Retest work piece with magnetic ink made with volatile carrier fluid

80. Demagnetization
Parts inspected by the magnetic particle method may sometimes have an objectionable residual magnetic field that may interfere with subsequent manufacturing operations or service of the component.
Demagnetization requires that the residual magnetic field is reversed and reduced by the inspector.
This process will scramble the magnetic domains and reduce the strength of the residual field to an acceptable level.
Magnetized
Demagnetized

81. Demagnetization (Cont.)
Using a solenoid is the simplest way to demagnetize a part
90% of all parts magnetized in MPI are demagnetised using a simple AC coil
Possible reasons for demagnetization include:
May interfere with welding and/or machining operations
Can effect gauges that are sensitive to magnetic fields if placed in close proximity.
Abrasive particles may adhere to components surface and cause and increase in wear to engines components, gears, bearings etc.

82. Advantages of Magnetic Particle Inspection
Can detect both surface and near sub-surface defects.
Can inspect parts with irregular shapes easily.
Precleaning of components is not as critical as it is for some other inspection methods. Most contaminants within a flaw will not hinder flaw detectability.
Fast method of inspection and indications are visible directly on the specimen surface.
Considered low cost compared to many other NDT methods.
Is a very portable inspection method especially when used with battery powered equipment.

83. Limitations of Magnetic Particle Inspection
Cannot inspect non-ferrous materials such as aluminum, magnesium or most stainless steels.
Inspection of large parts may require use of equipment with special power requirements.
Some parts may require removal of coating or plating to achieve desired inspection sensitivity.
Limited subsurface discontinuity detection capabilities. Maximum depth sensitivity is approximately 0.6” (under ideal conditions).
Post cleaning, and post demagnetization is often necessary.
Alignment between magnetic flux and defect is important

84. Glossary of Terms
Black Light: ultraviolet light which is filtered to produce a wavelength of approximately 365 nanometers. Black light will cause certain materials to fluoresce.
Central conductor: an electrically conductive bar usually made of copper used to introduce a circular magnetic field in to a test specimen.
Coil: an electrical conductor such a copper wire or cable that is wrapped in several or many loops that are brought close to one another to form a strong longitudinal magnetic field.

85. Glossary of Terms
Discontinuity: an interruption in the structure of the material such as a crack.
Ferromagnetic: a material such as iron, nickel and cobalt or one of it’s alloys that is strongly attracted to a magnetic field.
Heads: electrical contact pads on a wet horizontal magnetic particle inspection machine. The part to be inspected is clamped and held in place between the heads and shot of current is sent through the part from the heads to create a circular magnetic field in the part.
Leakage field: a disruption in the magnetic field. This disruption must extend to the surface of the part for particles to be attracted.

86. Glossary of Terms
Non-relevant indications: indications produced due to some intended design feature of a specimen such a keyways, splines or press fits.
Prods: two electrodes usually made of copper or aluminum that are used to introduce current in to a test part. This current in turn creates a circular magnetic field where each prod touches the part. (Similar in principal to a welding electrode and ground clamp).
Relevant indications: indications produced from something other than a design feature of a test specimen. Cracks, stringers, or laps are examples of relevant indications.

87. Glossary of Terms
Suspension: a bath created by mixing particles with either oil or water.
Yoke: a horseshoe magnet used to create a longitudinal magnetic field. Yokes may be made from permanent magnets or electromagnets.