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INSPECTION FUNDAMENTALS
DEFINITION
Inspection means “….An examinationof an item and comparison against a specific standard”.
Inspection system consists :
1. Regularly scheduled inspections of an aircraft, engine, propeller and component.
2. Reports made by mechanics or by the pilot or crew flying an aircraft and cabin crew.
INSPECTION METHODS
• Numerous inspection methods may be used, and would not restrict the use of higher level or more intense methods to satisfy the technician/inspector.
• When unsatisfactory condition encountered, additional methods may be employed such as : the use of inspection aids; removal of access panel or component.
BASIC INSPETION TASKS
1. Inspection; Examination against specific standard.
2. Non-Destructive Inspection; To supplement visual inspection and/or detect hidden defects
3. Age Exploration• Analysis of collected information from in-
service experience.
• Access resistance to deterioration process with respect to increasing age.
STRUCTURAL INSPECTIONS
2. External Surveillance,
– From a distance considered necessary to carry out adequate check,
1. General Visual,– Exposed areas of wings, fuselage, doors, doors cut out, engine
external and wheel wells.
4. Detailed External or Internal,– Close intensive visual of highly defined structural details or locations.
3. Internal Surveillance– From a distance considered necessary to carry out adequate check,
5. Special Detailed.– Specific locations or hidden details using specified NDI procedures.
Inspection Techniques
• Before starting an inspection, be certain all plates, access doors, fairings, and cowling have been opened or removed and the structure cleaned.
• When opening inspection plates and cowling, and before cleaning the area take note of any oil or other evidence of fluid leakage.
REQUIRED INSPECTION ITEMS (RII)
The person shall be appropriately certified, properly trained, qualified and authorized by Quality Assurance.
Defined as those maintenance and alteration which if not performed properly, or if improper parts or material are used, could result in endangering the aircraft operation safety;
Persons performing RII are considered to be under the supervision and control of quality assurance;
Decision of authorized RII inspector shall not be countermanded without approval of Director/Manager Quality Assurance or his designee;
The person who perform can not inspect, the person who inspect can not perform;
Checklist
• Always use a checklist when performing the inspection.
• The checklist may be of your own design, one provided by the manufacturer of the equipment/ aircraft/ engine ect being inspected, or one obtained from some other source.
The checklist should include the following:1. Fuselage and hull
group.2. Cabin and cockpit
group.3. Engine and nacelle
group.4. Landing gear group.5. Wing and center
section.6. Empennage group.7. Propeller group.8. Communication and
navigation group.9. Miscellaneous.
Aircraft Logs• "Aircraft logs" as used in this handbook is an inclusive
term which applies to the aircraft logbook and all supplemental records concerned with the aircraft.
• The logs and records provide a history of maintenance and operation, control of maintenance schedules, and data for time replacements of components or accessories.
• The aircraft logbook is the record in which all data concerning the aircraft is recorded.
• Information gathered in this log is used to determine the aircraft condition, date of inspections, time on airframe and engines.
• It reflects a history of all significant events occurring to the aircraft, its components, and accessories, and provides a place for indicating compliance with FAA Airworthiness Directives or manufacturers' service bulletins.
Special Inspections
1. Hard or Overweight Landing Inspection
2. Severe Turbulence Inspection
3. Other Abnormal loads
Publications
• Bulletins• Maintenance manual • Overhaul Manual• Structural Repair Manual• Federal Aviation
Regulations (FAR)• Airworthiness Directives• Type Certificate Data
Sheets
A.T.A. Specification No. 100
• The Air Transport Association of America (A.T.A.) issued the specifications for Manufacturers Technical Data June 1, 1956.
Quote: "This specification establishes a standard for the presentation of technical data, by an aircraft, aircraft accessory, or component manufacturer required for their respective products."Quote: "In order to standardize the treatment of subject matter and to simplify the user's problem in locating instructions, a uniform method of arranging material in all publications has been developed."
• The A.T.A. Specification 100 has the aircraft divided into systems such as electrical which covers the basic electrical system (ATA 2400).
• Numbering in each major system provides an arrangement for breaking the system down into several subsystems. Late model aircraft, both over and under the 12,500 dividing line, have their parts manuals and maintenance manuals arranged according to the A.T.A. coded system.
Non-destructive Inspection(NDT)
Preview
The use of noninvasive techniques to determine the integrity of a material, component or structure
or quantitatively measuresome characteristic ofan object.
i.e. Inspect or measure without doing harm.
DEFINITION
• Visual• Liquid Penetrant • Magnetic • Ultrasonic• Eddy Current• X-ray
Most Common NDT Methods
• Visual inspection is defined as the process of using the eye, alone or in conjunction with various aids, as the sensing mechanism from which judgments may be made about the condition of a unit to be inspected.
VISUAL INSPECTION
Most basic and common inspection method.Tools include fiberscopes, borescopes, magnifying glasses and mirrors. Pictures and Video Records
Robotic crawlers permit observation in hazardous or tight areas, such as air ducts, reactors, pipelines.
Portable video inspection unit with zoom allows
inspection of large tanks and vessels, railroad tank
cars, sewer lines.
VISUAL INSPECTION
• Over 80% of the inspections on large transport category aircraft are visual inspection.
• Visual inspection is usually the most economical and fastest way to obtain an early assessment of the condition of aircraft and its components.
• Most of the defect found on aircraft are found by visual inspections, and the airframe manufacturers and users depend on regular visual inspection to ensure the continued airworthiness of their aircraft
VISUAL INSPECTION
• Proficiency in visual inspection is crucial to the safe operation of aircraft.
• Such proficiency is gotten from the experience, but also by learning the methods developed by others.
• Visual inspection is an essential part of airplane maintenance.
• The visual inspection component of NDI required trained and experience personnel, using validated procedures, and appropriate calibration standard with effective, well maintained equipment in a well-managed maintenance environment
VISUAL INSPECTION
Visual Inspection
• Nondestructive testing by visual means is the oldest method of inspection.
• Defects which would escape the naked eye can be magnified so they will be visible.
• Telescopes, borescopes, and magnifying glasses aid in performing visual inspection.
Dye Penetrant Inspection
• Penetrant inspection is a nondestructive test for defects open to the surface in parts made of any nonporous material. It is used with equal success on such metals as aluminum, magnesium, brass, copper, cast iron, stainless steel, and titanium. It may also be used on ceramics, plastics, molded rubber, and glass.
• Penetrant inspection will detect such defects as surface cracks or porosity. These defects may be caused by fatigue cracks, shrinkage cracks, shrinkage porosity, cold shuts, grinding and heat treat cracks, seams, forging laps, and bursts. Penetrant inspection will also indicate a lack of bond between joined metals.
• The main disadvantage of penetrant inspection is that the defect must be open to the surface in order to let the penetrant get into the defect. For this reason, if the part in question is made of material which is magnetic, the use of magnetic particle inspection is generally recommended.
• Penetrant inspection depends for its success upon a penetrating liquid entering the surface opening and remaining in that opening, making it clearly visible to the operator. It calls for visual examination of the part after it has been processed, but the visibility of the defect is increased so that it can be detected. Visibility of the penetrating material is increased by the addition of dye which may be either one or two types - visible or fluorescent.
• The visible penetrant kit consists of dye penetrant, dye remover emulsifier and developer. The fluorescent penetrant inspection kit contains a black light assembly as well as spray cans of penetrant, cleaner, and developer. The light assembly consists of a power transformer, a flexible power cable, and a hand held lamp. Due to its size, the lamp may be used in almost any position or location.
Dye Penetrant Inspection _ cont’
• A liquid with high surface wetting characteristics is applied to the surface of the part and allowed time to seep into surface breaking defects.
• The excess liquid is removed from the surface of the part.
• A developer (powder) is applied to pull the trapped penetrant out the defect and spread it on the surface where it can be seen.
• Visual inspection is the final step in the process. The penetrant used is often loaded with a fluorescent dye and the inspection is done under UV light to increase test sensitivity.
Liquid Penetrant InspectionDye Penetrant Inspection
Magnetic Particle Inspection
• Magnetic particle inspection is a method of detecting invisible cracks and other defects in ferromagnetic materials, such as iron and steel.
• This method of inspection is a nondestructive test, which means it is performed on the actual part without damage to the part. It is not applicable to nonmagnetic materials.
• In rapidly rotating, reciprocating, vibrating, and other highly stressed aircraft parts, small defects often develop to the point that they cause complete failure of the part.
• Magnetic particle inspection has proved extremely reliable for the rapid detection of such defects located on or near the surface.
• In using this method of inspection, the location of the defect is indicated and the approximate size and shape are outlined.
The part is magnetized. Finely milled iron particles coated with a dye pigment are then applied to the specimen. These particles are attracted to magnetic flux leakage fields and will cluster to form an indication directly over the discontinuity. This indication can be visually detected under proper lighting conditions.
Magnetic Particle Inspection
• If a discontinuity is present, the magnetic lines of force will be disturbed and opposite poles will exist on either side of the discontinuity. The magnetized particles thus form a pattern in the magnetic field between the opposite poles. This pattern, known as an "indication," assumes the approximate shape of the surface projection of the discontinuity.
• A discontinuity may be defined as an interruption in the normal physical structure or configuration of a part such as a crack, forging lap, seam, inclusion, porosity, and the like. A discontinuity may or may not affect the usefulness of a part.
Magnetic Particle Inspection
Magnetic Particle Inspection
• If a discontinuity is present, the magnetic lines of force will be disturbed and opposite poles will exist on either side of the discontinuity. The magnetized particles thus form a pattern in the magnetic field between the opposite poles. This pattern, known as an "indication," assumes the approximate shape of the surface projection of the discontinuity.
• A discontinuity may be defined as an interruption in the normal physical structure or configuration of a part such as a crack, forging lap, seam, inclusion, porosity, and the like. A discontinuity may or may not affect the usefulness of a part.
Magnetic Particle Crack Indications
Radiography
• X and gamma radiations, because of their unique ability to penetrate material and disclose discontinuities, have been applied to the radiographic (X-ray) inspection of metal fabrications and nonmetallic products.
• The penetrating radiation is projected through the part to be inspected and produces an invisible or latent image in the film. When processed, the film becomes a radiograph or shadow picture of the object. This inspection medium, in a portable unit, provides a fast and reliable means for checking the integrity of airframe structures and engines.
RADIOGRAPHY
• Radiographic inspection techniques are used to locate defects or flaws in airframe structures or engines with little or no disassembly. This is in marked contrast to other types of nondestructive testing, which usually require removal, disassembly, and stripping of paint from the suspected part before it can be inspected. Due to the nature of X-ray, extensive training is required to become a qualified radiographer, and only qualified radiographers are allowed to operate the X-ray units.
• Three major steps in the X-ray process discussed in subsequent paragraphs are: (1) Exposure to radiation, including preparation, (2) processing of film, and (3) interpretation of the radiograph.
Radiography _ cont’
RadiographyThe radiation used in radiography testing is a higher energy (shorter wavelength) version of the electromagnetic waves that we see as visible light. The radiation can come from an X-ray generator or a radioactive source.
High Electrical Potential
Electrons-+
X-ray Generator or Radioactive Source Creates
Radiation
Exposure Recording Device
Radiation Penetrate the Sample
Film Radiography
Top view of developed film
X-ray film
The part is placed between the radiation source and a piece of film. The part will stop some of the radiation. Thicker and more dense area will stop more of the radiation.
= more exposure
= less exposure
The film darkness (density) will vary with the amount of radiation reaching the film through the test object.
Radiographic Images
Radiography _ cont’
Radiography _ cont’
Radiography _ cont’
Radiography _ cont’
Radiography _ cont’
Radiography _ cont’
Radiography _ cont’
High frequency sound waves are introduced into a material and they are reflected back from surfaces or flaws.
Reflected sound energy is displayed versus time, and inspector can visualize a cross section of the specimen showing the depth of features that reflect sound.
f
plate
crack
0 2 4 6 8 10
initial pulse
crack echo
back surface echo
Oscilloscope, or flaw detector screen
Ultrasonic Testing
Gray scale image produced using the sound reflected from the front surface of the coin
Gray scale image produced using the sound reflected from the back surface of the coin (inspected from “heads” side)
High resolution images can be produced by plotting signal strength or time-of-flight using a computer-controlled scanning system.
Ultrasonic Testing
• Ultrasonic detection equipment has made it possible to locate defects in all types of materials without damaging the material being inspected. Minute cracks, checks, and voids, too small to be seen by X-ray, are located by ultrasonic inspection. An ultrasonic test instrument requires access to only one surface of the material to be inspected and can be used with either straight line or angle beam testing techniques.
• Two basic methods are used for ultrasonic inspection. The first of these methods is immersion testing. In this method of inspection, the part under examination and the search unit are totally immersed in a liquid couplant, which may be water or any other suitable fluid.
• The second method is called contact testing, which is readily adapted to field use. In this method the part under examination and the search unit are coupled with a viscous material, liquid or a paste, which wets both the face of the search unit and the material under examination.
• There are two basic ultrasonic systems: (1) Pulsed and (2) resonance. The pulsed system may be either echo or through transmission; the echo is the most versatile of the two pulse systems.
Ultrasonic Testing _ cont’
Ultrasonic Testing _ cont’
Eddy Current Testing
• Electromagnetic analysis is a term which describes the broad spectrum of electronic test methods involving the intersection of magnetic fields and circulatory currents. The most widely used technique is the eddy current.
• Eddy currents are composed of free electrons, which are made to "drift" through metal, under the influence of an induced electromagnetic field.
Eddy Current Testing
• Eddy current is used in aircraft maintenance to inspect jet engine turbine shaft and vanes, wing skins, wheels, bolt holes, and spark plug bores for cracks, heat or frame damage. In aircraft manufacturing plants, eddy current is used to inspect castings, stampings, machine parts, forgings, and extrusions.
Sioux City, Iowa, July 19, 1989A defect that went undetected in an engine disk was responsible for the crash of United Flight 232.
Crash of United Flight 232