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Magnetic Flux Leakage

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MFL Level II Set 1

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1. What is the fundamental principle of Magnetic Flux Leakage (MFL) testing?
Electrical conductivity variation Leakage of magnetic field caused by discontinuities Reflection of ultrasonic waves Thermal expansion of metal
2. MFL testing is applicable primarily to:
Non-metallic materials Ferromagnetic materials Plastics Aluminum alloys
3. Which defect type is most effectively detected by MFL?
Tight fatigue cracks Lamination defects Metal loss due to corrosion Internal voids
4. In MFL testing, the test object must first be:
Electrically grounded Magnetized Heated Polished
5. Magnetic flux leakage occurs when:
Magnetic permeability increases Magnetic field encounters a discontinuity Temperature rises Electrical current flows
6. Which sensor is commonly used in MFL inspection tools?
Thermocouple Hall effect sensor Strain gauge Ultrasonic transducer
7. Ferromagnetic materials have:
Low permeability High magnetic permeability Zero magnetic permeability Constant permeability
8. The magnetic field used in MFL testing is typically produced by:
Permanent magnets or electromagnets Laser beams Radio waves X-rays
9. The purpose of magnetizing the test object is to:
Increase electrical conductivity Saturate the material with magnetic flux Increase hardness Reduce corrosion
10. Flux leakage signals increase when:
Defect size decreases Magnetization decreases Metal loss increases Surface becomes smoother
11. Lift-off refers to:
Distance between magnet poles Distance between sensor and test surface Distance between defects Thickness of coating
12. MFL inspection is widely used for:
Ceramic inspection Pipeline inspection Wood inspection Concrete inspection
13. The magnetic flux path prefers to travel through:
Air Steel Vacuum Plastic
14. When a defect is present, magnetic flux tends to:
Disappear Leak out of the material Reverse direction Stop completely
15. Which condition produces the strongest leakage signal?
Small shallow pit Deep corrosion pit Smooth surface Thick coating
16. Calibration standards in MFL are used to:
Adjust equipment sensitivity Change material properties Increase magnet strength Reduce noise
17. The output signal of an MFL sensor represents:
Temperature change Magnetic flux variation Pressure change Electrical resistance
18. Which factor affects MFL signal strength?
Magnetization level Material thickness Sensor distance All of the above
19. MFL inspection is best suited for detecting:
Surface paint defects Volumetric metal loss Micro-cracks Grain boundaries
20. Which industry heavily uses MFL technology?
Textile industry Oil and gas industry Food processing Electronics
21. MFL testing does not require:
Surface cleaning Magnetization Sensors Data acquisition
22. Magnetic saturation ensures:
Maximum flux leakage at defects Reduced signal detection Lower permeability Higher electrical conductivity
23. Which parameter influences defect detectability?
Defect depth Defect width Magnetization strength All of the above
24. Magnetic flux density is represented by:
H B μ I
25. Magnetic permeability represents:
Resistance to magnetization Ability to carry magnetic flux Electrical resistance Heat transfer capability
26. In MFL inspection tools, data is typically recorded using:
Digital data acquisition systems Analog thermometers Pressure gauges Multimeters
27. False indications may be caused by:
Surface roughness Weld geometry Sensor vibration All of the above
28. MFL is ineffective for inspecting:
Carbon steel Cast iron Austenitic stainless steel Low alloy steel
29. Which parameter is critical for MFL inspection accuracy?
Magnet spacing Sensor spacing Magnet strength All of the above
30. MFL inspection systems are often mounted on:
Robotic scanners Pipelines pigs Tank floor scanners All of the above
31. Signal interpretation in MFL is based on:
Signal amplitude Signal shape Signal width All of the above
32. High magnetization levels help:
Increase sensitivity to metal loss Reduce signal strength Eliminate defects Increase noise
33. Which device converts magnetic signals into electrical signals?
Sensor Pump Valve Heater
34. MFL testing is considered:
Destructive testing Semi-destructive testing Non-destructive testing Thermal testing
35. A uniform metal thickness results in:
Flux leakage Uniform magnetic field Magnetic reversal Zero magnetization
36. Increasing sensor lift-off will:
Increase signal strength Reduce signal strength Increase permeability Improve accuracy
37. MFL inspection can detect:
Pitting corrosion Wall thinning Metal loss All of the above
38. Data interpretation is typically performed by:
Level I technician Level II technician Helper Operator only
39. Which parameter helps determine defect size?
Signal amplitude Signal width Signal pattern All of the above
40. MFL inspection results are typically presented as:
Signal graphs or maps Temperature charts Pressure curves Electrical diagrams
41. If calibration results are outside acceptable limits, the operator should:
Continue inspection Recalibrate equipment Ignore the issue Increase scanning speed
42. During inspection, sensor signals should be monitored for:
Signal amplitude changes Signal pattern changes Noise levels All of the above
43. Indications detected during inspection should be:
Recorded Evaluated Reported All of the above
44. Defect sizing in MFL inspection is typically based on:
Signal amplitude Signal width Signal pattern All of the above
45. Excessive vibration of the inspection head may cause:
False indications Increased sensitivity Reduced permeability Magnet failure
46. The inspection report should include:
Equipment identification Calibration details Inspection results All of the above
47. Inspection procedures are developed by:
Level I personnel Level II personnel Level III personnel Equipment operator
48. Acceptance criteria used during inspection are defined in:
Inspection procedure Applicable code or standard Client specification All of the above
49. The Level II technician must ensure that:
Inspection follows written procedure Equipment operates correctly Data is properly recorded All of the above
50. If a defect indication exceeds acceptance limits, it should be:
Ignored Documented and reported Removed immediately Covered with coating
51. The inspection area must be clearly:
Marked Documented Recorded All of the above
52. MFL equipment should be inspected for damage:
Before use During inspection After use All of the above
53. Sensors in MFL systems detect:
Leakage magnetic fields Surface temperature Electrical current Sound waves
54. The operator must ensure magnets are:
Properly aligned Securely mounted Functioning correctly All of the above
55. Environmental conditions affecting inspection may include:
Temperature Moisture Surface contamination All of the above
56. Data interpretation should be performed by:
Certified Level II or Level III personnel Helper Equipment operator only Any technician
57. The purpose of inspection records is to:
Provide traceability Document inspection results Support quality assurance All of the above
58. If excessive noise appears in the signal, the operator should check:
Sensor alignment Lift-off distance Equipment condition All of the above
59. Inspection results must be:
Accurate Documented Traceable All of the above
60. The final inspection report should be reviewed by:
Level I technician Level II technician Level III or authorized personnel Helper
61. Tank Floor Inspection During an MFL tank floor scan, a signal shows a high amplitude narrow peak at one location while surrounding signals remain uniform. What is the most likely cause?
Uniform wall thinning Localized corrosion pit Coating thickness variation Sensor lift-off increase
62. Tank Floor Inspection An MFL scan shows broad low-amplitude signals across a large area of the tank bottom. This most likely indicates:
Uniform corrosion thinning Deep isolated pit Sensor malfunction Weld crack
63. Tank Floor Inspection A signal appears repeatedly at regular intervals along a weld seam. What is the most likely interpretation?
Equipment noise Weld geometry effect Severe corrosion Magnetic saturation
64. Pipeline Pig Inspection During pipeline MFL pigging, a sharp high-amplitude signal is recorded with a narrow signal width. This usually indicates:
Localized metal loss Uniform corrosion Pipe coating defect Pipe temperature variation
65. Pipeline Pig Inspection An MFL pig records continuous low-level signals over several meters.This is most likely:
Mechanical damage Uniform wall thinning Sensor malfunction Debris in pipeline
66. Pipeline Pig Inspection If the MFL pig shows multiple sharp signals close together, the most probable cause is:
Clustered corrosion pits Temperature fluctuation Coating variation Pipe misalignment
67. Pipeline Pig Inspection A signal suddenly disappears after strong indications earlier in the run. This may indicate:
Pig sensor failure Pipe wall thickening Reduced magnetization Improved coating
68. Tube Inspection During tube MFL inspection, a signal appears with moderate amplitude and moderate width.This usually corresponds to:
Medium depth corrosion pit Small surface scratch Tube material change Tube coating variation
69. Tube Inspection A very narrow and sharp signal peak is detected in a tube inspection scan. The most likely cause is:
Small localized pit Uniform corrosion Tube vibration Magnetic saturation
70. Tube Inspection Repeated signals appearing at equal spacing along the tube length are likely due to:
Manufacturing marks or periodic defects Random corrosion Magnet failure Sensor lift-off